{"meta":{"query_hash":"1c12a8c47162","filters":{"venue":"Nanophotonics"},"cohort_total":96,"direct_labels_cover":0,"predictions_cover":96,"exported":96,"export_cap":100000,"truncated":false,"label_status":"direct model label, unvalidated","prediction_status":"machine_predicted_unvalidated (Codex and Gemma teacher distillation)","score_status":"score_only:v0-immature-baseline","snapshot":{"source":"OpenAlex, pinned release, all 482 partitions","release":"2026-06-24","frame_built":"2026-07-12"},"permalink":"https://metacan.xera.ac/q/1c12a8c47162","api":"https://metacan.xera.ac/api/v1/cohort?venue=Nanophotonics"},"results":[{"id":"W1972316237","doi":"10.1515/nanoph-2013-0034","title":"Progress in silicon platforms for integrated optics","year":2013,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":40,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Waterloo","funders":"","keywords":"Silicon photonics; Computer science; Microelectronics; Wafer; Photonics; Nanotechnology; Systems engineering; Engineering; Materials science; Optoelectronics","score_opus":0.00921345563552585,"score_gpt":0.22442732557922232,"score_spread":0.21521386994369646,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W1972316237","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9934741,0.0009405402,0.0002478126,0.00003230503,0.00030434312,0.00077218097,0.000011737106,0.00022459948,0.0039923755],"genre_scores_gemma":[0.98643684,0.00014519086,0.012667615,0.00008074511,0.000013770838,0.00046934249,0.000026459988,0.000042604774,0.00011740558],"study_design_codex":"design_other","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.999095,0.0000024613796,0.0002568788,0.00015582283,0.00010147856,0.00038835168],"domain_scores_gemma":[0.9995776,0.000068216024,0.000020370158,0.0001846449,0.000059846738,0.00008931766],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00008858817,0.0001632143,0.00020947063,0.000056325094,0.000025465522,0.00005425489,0.00018332772,0.00016900971,0.00007732728],"category_scores_gemma":[0.000023862318,0.00013441948,0.000055035856,0.0002159634,0.00004300143,0.0001897908,0.000021231663,0.0001845323,0.00009861534],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00055422663,0.002380128,0.041960064,0.006903323,0.0011291511,0.00016805685,0.0080372915,0.059012346,0.1344343,0.22611809,0.01465684,0.5046462],"study_design_scores_gemma":[0.0005946753,0.00006896562,0.001256003,0.000050178132,0.000007427037,0.0000025853012,0.00010184903,0.9721984,0.016896758,0.0018862337,0.006701372,0.00023551116],"about_ca_topic_score_codex":0.000014618549,"about_ca_topic_score_gemma":0.000030716685,"teacher_disagreement_score":0.9131861,"about_ca_system_score_codex":0.00009260092,"about_ca_system_score_gemma":0.000033046963,"threshold_uncertainty_score":0.5481467},"labels":[],"label_agreement":null},{"id":"W1982522234","doi":"10.1515/nanoph-2015-0003","title":"Optical control of the spin of a magnetic atom in a semiconductor quantum dot","year":2014,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Semiconductor Quantum Structures and Devices","field":"Physics and Astronomy","cited_by":11,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Indigenous and Northern Affairs Canada; Centre National de la Recherche Scientifique","keywords":"Excited state; Atom (system on chip); Condensed matter physics; Quantum dot; Physics; Spin (aerodynamics); Excitation; Spin states; Coherent control; Atomic physics; Spins; Spin engineering; Magnetic field; Population; Magnetic semiconductor; Spin polarization; Laser; Quantum mechanics; Electron; Ferromagnetism","score_opus":0.007057073966268958,"score_gpt":0.2310221791226225,"score_spread":0.22396510515635354,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W1982522234","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99790376,0.0003144539,0.000050960545,0.0000565817,0.00028711205,0.00024312329,0.00004420079,0.0000061420815,0.0010936477],"genre_scores_gemma":[0.9995238,0.0000032702237,0.00030161027,0.00007406064,0.000041061347,0.000011239766,0.000002823367,0.000015223603,0.000026916712],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99885285,0.00006850662,0.000433331,0.0002052154,0.00020360357,0.00023650064],"domain_scores_gemma":[0.9990947,0.00015024058,0.00021511996,0.00042600202,0.000064444386,0.00004949412],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00017805623,0.0001536841,0.00037861257,0.00004045381,0.000027337603,0.0000112206335,0.00033409544,0.00007137792,0.0002555836],"category_scores_gemma":[0.000021848798,0.00010534924,0.00015992312,0.00021468844,0.00013587724,0.000043157434,0.00005984263,0.00018892477,0.000004046502],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000052881223,0.0001202065,0.085399196,0.00006134736,0.000033977907,4.073598e-7,0.00032775282,0.00010067413,0.70254767,0.21029848,0.000049177645,0.0010082335],"study_design_scores_gemma":[0.009630485,0.00080747786,0.112048425,0.0004585162,0.00024191118,0.000008928392,0.0012522864,0.057830174,0.7369261,0.061976705,0.01786659,0.00095243356],"about_ca_topic_score_codex":0.00038352326,"about_ca_topic_score_gemma":0.000016519283,"teacher_disagreement_score":0.14832178,"about_ca_system_score_codex":0.000013506493,"about_ca_system_score_gemma":0.000092692935,"threshold_uncertainty_score":0.4296017},"labels":[],"label_agreement":null},{"id":"W1989056903","doi":"10.1515/nanoph-2014-0014","title":"Enhanced Raman scattering in graphene by plasmonic resonant Stokes emission","year":2014,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":27,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Ottawa","funders":"","keywords":"Graphene; Raman scattering; Plasmon; Materials science; Laser linewidth; Raman spectroscopy; Surface plasmon polariton; Optoelectronics; Scattering; Surface plasmon; Optics; Nanotechnology; Physics; Laser","score_opus":0.006830281421320648,"score_gpt":0.21872656944260171,"score_spread":0.21189628802128108,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W1989056903","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9940589,0.0008558286,0.0008265805,0.00007381078,0.00028072178,0.00020392999,0.000015475094,0.00023707541,0.0034476884],"genre_scores_gemma":[0.995594,0.0014707792,0.0022772627,0.00004256417,0.000003901406,0.000046468787,0.000021126181,0.00005989696,0.0004839749],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.998144,0.00005690947,0.0003569621,0.00034150414,0.0003857432,0.00071489625],"domain_scores_gemma":[0.9992068,0.0001668905,0.000033222685,0.0003788511,0.00002823962,0.00018599669],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00047185793,0.00025961635,0.00032785264,0.00014850598,0.00008604892,0.00005373344,0.00035113815,0.00019045692,0.000061016373],"category_scores_gemma":[0.00006545114,0.00025486643,0.00007318678,0.0004201499,0.000054844386,0.00015875403,0.000074310796,0.0004933579,0.00008920415],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000045782668,0.000052929543,0.00079137814,0.000108845226,0.000020136282,0.000010190408,0.00026126715,0.018775819,0.97026396,0.000055097873,0.0031766498,0.00643793],"study_design_scores_gemma":[0.0007088816,0.00005005343,0.0005697059,0.00010325277,0.0000037409384,0.0000032276346,0.00004840137,0.49167532,0.48715362,0.00007401782,0.019308953,0.00030082322],"about_ca_topic_score_codex":0.000039993494,"about_ca_topic_score_gemma":0.00005327377,"teacher_disagreement_score":0.48311034,"about_ca_system_score_codex":0.00017012683,"about_ca_system_score_gemma":0.000038545175,"threshold_uncertainty_score":0.99999034},"labels":[],"label_agreement":null},{"id":"W2343948806","doi":"10.1515/nanoph-2016-0029","title":"Multifrequency sources of quantum correlated photon pairs on‐chip: a path toward integrated Quantum Frequency Combs","year":2016,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":302,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut National de la Recherche Scientifique","funders":"Engineering and Physical Sciences Research Council; Natural Sciences and Engineering Research Council of Canada; Fonds de recherche du Québec – Nature et technologies; European Commission; City University of Hong Kong","keywords":"Photonics; Quantum technology; Quantum; Quantum information science; Computer science; Photon; Quantum sensor; Quantum imaging; Qubit; Quantum network; Physics; Quantum information; Electronic engineering; Optoelectronics; Quantum entanglement; Quantum mechanics; Open quantum system; Engineering","score_opus":0.013743747555536721,"score_gpt":0.2159225600743311,"score_spread":0.20217881251879438,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2343948806","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9886134,0.0013493182,0.0014665319,0.00008352849,0.001190503,0.00051857275,0.000253403,0.00073087687,0.0057938443],"genre_scores_gemma":[0.9970621,0.0013100366,0.0011785431,0.00010160905,0.000019300116,0.00006454133,0.00002716933,0.00011215688,0.0001245627],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99725133,0.000090108326,0.00087754143,0.00051290396,0.000503803,0.00076433644],"domain_scores_gemma":[0.99821573,0.0004250333,0.00019027243,0.000699643,0.00019106844,0.000278228],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0003278415,0.0005503476,0.000734235,0.00017981304,0.00008650219,0.00003494772,0.0006008392,0.00046829594,0.00045738704],"category_scores_gemma":[0.00025631444,0.0003777236,0.00026558334,0.0005863479,0.0002541875,0.00021079682,0.000056235865,0.0005086169,0.00030085127],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0005802393,0.0012779046,0.008843203,0.0011496958,0.0009856533,0.00041376997,0.00381489,0.0022774164,0.8454594,0.12380772,0.001808306,0.009581816],"study_design_scores_gemma":[0.0040896474,0.0016369945,0.0022320293,0.0019680916,0.00017145257,0.000045260917,0.0005983359,0.6691282,0.2991016,0.010125056,0.009185998,0.0017173748],"about_ca_topic_score_codex":0.0003043662,"about_ca_topic_score_gemma":0.000023416804,"teacher_disagreement_score":0.66685075,"about_ca_system_score_codex":0.00025806893,"about_ca_system_score_gemma":0.00016327496,"threshold_uncertainty_score":0.9998675},"labels":[],"label_agreement":null},{"id":"W2344825353","doi":"10.1515/nanoph-2015-0026","title":"Mesoscale cavities in hollow‐core waveguides for quantum optics with atomic ensembles","year":2016,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":5,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Waterloo","funders":"","keywords":"Photon; Core (optical fiber); Quantum optics; Optics; Nonlinear optics; Optoelectronics; Laser; Physics; Quantum; Nanophotonics; Materials science; Quantum mechanics","score_opus":0.015545836429506122,"score_gpt":0.2246191098644812,"score_spread":0.20907327343497506,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2344825353","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9932147,0.0008875431,0.001141634,0.00007785018,0.00026060635,0.00037102262,0.00008440401,0.00020259319,0.0037596072],"genre_scores_gemma":[0.9901819,0.00072988716,0.008231641,0.00005886098,0.000024510922,0.00012437577,0.0000061440255,0.00006858085,0.0005740981],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9987942,0.000008189239,0.00029128735,0.00024283757,0.00016906593,0.000494447],"domain_scores_gemma":[0.9992504,0.00027270697,0.000033722867,0.0002903348,0.00005212653,0.0001006843],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00015089125,0.00023719028,0.00032311227,0.00007276034,0.00004881042,0.000029885367,0.00021157257,0.0001570464,0.000022462362],"category_scores_gemma":[0.000040458537,0.00015549162,0.000074813564,0.00014287962,0.00009425331,0.00014630044,0.00002918976,0.00010389121,0.000025166331],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0009141807,0.00038398072,0.010098225,0.0019565825,0.00053445343,0.00025271933,0.0027120581,0.0069511635,0.67218184,0.2906203,0.0022130837,0.011181416],"study_design_scores_gemma":[0.005550749,0.0005887974,0.0018844701,0.0010207649,0.00012213952,0.00005573746,0.000698719,0.5380417,0.39503893,0.015840003,0.03954909,0.0016088707],"about_ca_topic_score_codex":0.000021137972,"about_ca_topic_score_gemma":0.00027325444,"teacher_disagreement_score":0.53109056,"about_ca_system_score_codex":0.00013811614,"about_ca_system_score_gemma":0.000073980525,"threshold_uncertainty_score":0.6340765},"labels":[],"label_agreement":null},{"id":"W2518204252","doi":"10.1515/nanoph-2016-0111","title":"Recent advancements in plasmon‐enhanced promising third‐generation solar cells","year":2016,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Gold and Silver Nanoparticles Synthesis and Applications","field":"Materials Science","cited_by":98,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Université du Québec à Montréal; Institut National de la Recherche Scientifique","funders":"","keywords":"Materials science; Plasmon; Plasmonic solar cell; Photovoltaics; Surface plasmon resonance; Photovoltaic system; Optoelectronics; Hybrid solar cell; Nanotechnology; Absorption (acoustics); Quantum dot solar cell; Solar cell; Polymer solar cell; Nanoparticle","score_opus":0.021433925045303063,"score_gpt":0.2455247056810902,"score_spread":0.22409078063578713,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2518204252","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9978159,0.00012974905,0.00042428827,0.00034201783,0.0003140418,0.00030209403,0.000015898195,0.000043167147,0.0006128295],"genre_scores_gemma":[0.99452525,0.0012494241,0.0036736357,0.00012319925,0.000027936569,0.00010022814,0.0000024267777,0.000013044188,0.00028485188],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9988154,0.00004526348,0.00030797353,0.0003310451,0.00019854796,0.00030176967],"domain_scores_gemma":[0.99945956,0.000045342083,0.000099317745,0.00027520122,0.000056824814,0.00006374365],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00029500516,0.00011659895,0.00014863428,0.000035176567,0.00011239414,0.000050303435,0.00016498019,0.00006302714,0.00034001953],"category_scores_gemma":[0.000036735713,0.00008122282,0.000030697916,0.00016563774,0.000034957608,0.00019427377,0.0000403841,0.000040267754,0.00035830526],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000015391704,0.000096519594,0.000058404734,0.0000032609532,0.0000012396027,9.040526e-7,0.00010067808,0.000059814833,0.9806258,0.00013982833,0.0001602002,0.018737976],"study_design_scores_gemma":[0.0004789563,0.000030360618,0.000063958934,0.000043465123,0.000004281681,4.41276e-7,0.000019294655,0.00061472325,0.9735114,0.00014443252,0.024958126,0.00013057313],"about_ca_topic_score_codex":0.000010306661,"about_ca_topic_score_gemma":0.000062547115,"teacher_disagreement_score":0.024797926,"about_ca_system_score_codex":0.00011020767,"about_ca_system_score_gemma":0.000065418615,"threshold_uncertainty_score":0.46054086},"labels":[],"label_agreement":null},{"id":"W2552461229","doi":"10.1515/nanoph-2016-0135","title":"Integrated nanoplasmonic waveguides for magnetic, nonlinear, and strong‐field devices","year":2016,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":24,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Alberta","funders":"","keywords":"Plasmon; Photonics; CMOS; Metamaterial; Optoelectronics; Bandwidth (computing); Waveguide; Nonlinear optics; Materials science; Nanotechnology; Nonlinear system; Physics; Computer science; Telecommunications","score_opus":0.014134719525555315,"score_gpt":0.24075727144034478,"score_spread":0.22662255191478947,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2552461229","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9924121,0.002451326,0.0015609615,0.00032579814,0.0003371366,0.00042870533,0.00016118241,0.00025774108,0.002065052],"genre_scores_gemma":[0.89866716,0.0033652633,0.09398635,0.00012903973,0.000014153507,0.00015959155,0.000021551376,0.00010962106,0.0035472596],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99862146,0.000018158253,0.0002878842,0.00029580065,0.00020848027,0.00056823675],"domain_scores_gemma":[0.99878484,0.00064826285,0.000027119966,0.00026591812,0.00010708983,0.00016675815],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00024061627,0.00024445597,0.00027506612,0.00008217846,0.00009144475,0.00006442884,0.00023116944,0.00021663461,0.00015884067],"category_scores_gemma":[0.00016350693,0.00017149205,0.00006991987,0.00015428179,0.00006959661,0.00014647993,0.000056861794,0.00016580442,0.00005827592],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00060491264,0.00019231571,0.011343059,0.00086183654,0.000444372,0.00006603453,0.00040799603,0.0017778988,0.72846323,0.0027633375,0.031405624,0.22166938],"study_design_scores_gemma":[0.0017691741,0.00047536293,0.0002748818,0.00015373321,0.000033345972,0.000020247424,0.0001146984,0.46492296,0.23922434,0.00020301508,0.29229897,0.00050925964],"about_ca_topic_score_codex":0.000018199831,"about_ca_topic_score_gemma":0.00020779361,"teacher_disagreement_score":0.48923892,"about_ca_system_score_codex":0.00009661786,"about_ca_system_score_gemma":0.00009496273,"threshold_uncertainty_score":0.6993243},"labels":[],"label_agreement":null},{"id":"W2556892520","doi":"10.1515/nanoph-2016-0120","title":"Optical transmission theory for metal‐insulator‐metal periodic nanostructures","year":2016,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":6,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Polytechnique Montréal","funders":"","keywords":"Dielectric; Materials science; Diffraction; Optics; Condensed matter physics; Nanostructure; Classification of discontinuities; Scattering; Computational physics; Physics; Optoelectronics; Nanotechnology; Mathematical analysis; Mathematics","score_opus":0.010470444272358853,"score_gpt":0.2337153630293917,"score_spread":0.22324491875703284,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2556892520","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.98308104,0.0020007277,0.011236267,0.00013014415,0.0004889594,0.00043298793,0.00009371721,0.00028624872,0.0022499328],"genre_scores_gemma":[0.9775685,0.0006443415,0.019652244,0.000031773347,0.00001131204,0.00007422284,0.00001005417,0.00007802665,0.0019295135],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9984605,0.000035948753,0.00026889084,0.0002959978,0.00034647717,0.0005922268],"domain_scores_gemma":[0.9990299,0.00036147606,0.00001994167,0.00030640396,0.000060307335,0.00022197973],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.0003881851,0.0002507868,0.00031346967,0.00007475201,0.00013125273,0.000038388775,0.00029628593,0.00025800234,0.00042312077],"category_scores_gemma":[0.00011864859,0.00016180791,0.00020645534,0.00013869035,0.00012337096,0.00013140206,0.00003132125,0.00018494873,0.00008035549],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00023044666,0.00003829364,0.00008257656,0.000121650264,0.00017382021,0.000018868064,0.00016769671,0.001579598,0.95921695,0.008846417,0.0010643131,0.028459387],"study_design_scores_gemma":[0.0022013367,0.00020881249,0.00031583695,0.000078152705,0.00007763291,0.000037835147,0.000058898026,0.09487482,0.7294086,0.0057013324,0.16642185,0.0006148701],"about_ca_topic_score_codex":9.2904725e-7,"about_ca_topic_score_gemma":0.0000015144682,"teacher_disagreement_score":0.2298083,"about_ca_system_score_codex":0.00009879454,"about_ca_system_score_gemma":0.0000991426,"threshold_uncertainty_score":0.6598335},"labels":[],"label_agreement":null},{"id":"W2597515552","doi":"10.1515/nanoph-2016-0174","title":"Fundamentals and applications of SERS‐based bioanalytical sensing","year":2017,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Gold and Silver Nanoparticles Synthesis and Applications","field":"Materials Science","cited_by":201,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"McGill University","funders":"Anhui University of Finance and Economics; Türkiye Bilimsel ve Teknolojik Araştırma Kurumu","keywords":"Nanotechnology; Bioanalysis; Materials science; Raman scattering; Biosensor; Plasmon; Flexibility (engineering); Nanomaterials; Raman spectroscopy; Optoelectronics; Physics; Optics","score_opus":0.019034922684488566,"score_gpt":0.2739837644910161,"score_spread":0.2549488418065275,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2597515552","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99744755,0.00006140904,0.0005258077,0.0003665689,0.00002667893,0.00017300072,0.000027064554,0.000019291487,0.0013526215],"genre_scores_gemma":[0.9912588,0.000015787731,0.008554684,0.000075878306,0.000011339235,0.00001268989,0.0000011449639,0.000006617207,0.000063082916],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9993831,0.000012918034,0.00016874706,0.00018410324,0.0001177348,0.00013342136],"domain_scores_gemma":[0.99921215,0.000052591957,0.00013697686,0.0004931658,0.00003622162,0.00006888447],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00017949281,0.00006982951,0.00013819912,0.000015308498,0.00035066908,0.00009857533,0.0001719352,0.000041736752,0.00015146822],"category_scores_gemma":[0.000026892465,0.000061307546,0.00003717757,0.0000401134,0.00025147732,0.00006473585,0.000075122516,0.00003073401,0.000050234466],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0000053219137,0.000042200732,0.0010494649,0.000011485176,0.0000026151067,4.632773e-7,0.00002457114,0.000008695395,0.99216944,0.0019279164,0.00004414003,0.004713697],"study_design_scores_gemma":[0.00019022207,0.00001643964,0.0016579049,0.0000138847,0.000026184225,0.0000018216855,0.000041535313,0.004530171,0.98525786,0.0005869088,0.0075941365,0.00008292392],"about_ca_topic_score_codex":0.000071452116,"about_ca_topic_score_gemma":0.000017111886,"teacher_disagreement_score":0.008028876,"about_ca_system_score_codex":0.000013013055,"about_ca_system_score_gemma":0.000034120723,"threshold_uncertainty_score":0.26970986},"labels":[],"label_agreement":null},{"id":"W2774463639","doi":"10.1515/nanoph-2017-0119","title":"Design, concepts, and applications of electromagnetic metasurfaces","year":2018,"lang":"en","type":"preprint","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":9,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Polytechnique Montréal","funders":"Natural Sciences and Engineering Research Council of Canada","keywords":"Birefringence; Context (archaeology); Tensor (intrinsic definition); Computer science; Harmonic; Nonlinear system; Physics; Optics; Mathematics; Geometry; Acoustics; Geology; Quantum mechanics","score_opus":0.02538549728430841,"score_gpt":0.29046356851670896,"score_spread":0.26507807123240057,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2774463639","genre_codex":"empirical","genre_gemma":"methods","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":null,"domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.97242516,0.010134867,0.014121716,0.00004809945,0.0004078274,0.002026561,0.00032114878,0.000098008975,0.00041661778],"genre_scores_gemma":[0.38326275,0.0048936983,0.6091594,0.00009270911,0.00008754553,0.001857855,0.00009997234,0.00008576329,0.0004602933],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99769026,0.00023098622,0.0006896523,0.00071840483,0.00033930526,0.0003313928],"domain_scores_gemma":[0.9976864,0.00015818594,0.00068927277,0.0010301691,0.00031802704,0.00011798419],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0012444041,0.00032601063,0.00072685373,0.00006301858,0.0001540308,0.0001198327,0.00062303717,0.00031230797,0.000836693],"category_scores_gemma":[0.000051901356,0.00029583662,0.00008426004,0.00017260242,0.0004305325,0.00005202497,0.00050306704,0.00017591046,0.00012225073],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000017586557,0.000055493423,0.0000064581022,0.00021827787,0.000028393744,2.7030572e-7,0.00012052175,0.00020920238,0.9981221,0.0006271925,0.0002988128,0.00029570443],"study_design_scores_gemma":[0.00019536627,0.00013521638,0.000042853284,0.00004560538,0.00024432153,0.000004902128,0.000021189744,0.000999538,0.97095925,0.0067128967,0.02034232,0.0002965294],"about_ca_topic_score_codex":0.00008494743,"about_ca_topic_score_gemma":0.0000070892984,"teacher_disagreement_score":0.5950377,"about_ca_system_score_codex":0.00003297885,"about_ca_system_score_gemma":0.00032715002,"threshold_uncertainty_score":0.9999494},"labels":[],"label_agreement":null},{"id":"W2800600879","doi":"10.1515/nanoph-2017-0117","title":"Huygens’ metasurfaces from microwaves to optics: a review","year":2018,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":230,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Toronto","funders":"","keywords":"Cloaking; Optics; Physics; Huygens–Fresnel principle; Electromagnetic radiation; Microwave; Refraction; Electromagnetic field; Metamaterial; Reflection (computer programming); Computer science","score_opus":0.07453225667005703,"score_gpt":0.3605010464439401,"score_spread":0.28596878977388307,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2800600879","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.0009892132,0.99051493,0.000043852142,0.000064087944,0.0019208947,0.0030991992,0.002717399,0.00015316565,0.00049724185],"genre_scores_gemma":[1.7874211e-7,0.87853307,0.11869554,0.0006554163,0.0001416044,0.0007778328,0.00034907873,0.00012760848,0.0007196492],"study_design_codex":"bench_or_experimental","study_design_gemma":"not_applicable","domain_scores_codex":[0.9951579,0.00047348306,0.0017245963,0.0013827973,0.00057731406,0.00068389944],"domain_scores_gemma":[0.9958705,0.00027374315,0.0010139894,0.0021943625,0.000268512,0.00037891255],"candidate_categories":["metaepi_narrow","insufficient_payload"],"consensus_categories":["insufficient_payload"],"category_scores_codex":[0.0018020493,0.0008504277,0.0038361016,0.000091776164,0.00024124277,0.00028179842,0.0016746719,0.00041518654,0.003833264],"category_scores_gemma":[0.00033435944,0.0006419789,0.00069482985,0.0006335601,0.00012690279,0.00010945938,0.0004951076,0.00022096315,0.019874897],"study_design_candidate":"not_applicable","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000025137797,0.00041407646,1.8757326e-7,0.13937531,0.0009459286,0.000038953185,0.00027361556,0.0000047743333,0.49611095,0.00069655967,0.12905702,0.23305748],"study_design_scores_gemma":[0.00006490456,0.000048345082,7.34134e-8,0.025626805,0.0023356485,0.000011978458,0.0000036823492,0.000002481692,0.013253659,0.000076398974,0.95790714,0.00066888396],"about_ca_topic_score_codex":0.000094255534,"about_ca_topic_score_gemma":0.00002168174,"teacher_disagreement_score":0.8288501,"about_ca_system_score_codex":0.00012405805,"about_ca_system_score_gemma":0.0005288215,"threshold_uncertainty_score":0.99960315},"labels":[],"label_agreement":null},{"id":"W2898678965","doi":"10.1515/nanoph-2018-0108","title":"Multiperiodic nanohole array for high precision sensing","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":15,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Polytechnique Montréal","funders":"","keywords":"Optics; Monochromatic color; Surface plasmon resonance; Plasmon; Refractive index; Materials science; Surface plasmon; Resonance (particle physics); Transmission (telecommunications); Image resolution; Extraordinary optical transmission; Optoelectronics; Physics; Surface plasmon polariton; Nanotechnology; Telecommunications; Computer science","score_opus":0.014714367119588845,"score_gpt":0.24985807170082527,"score_spread":0.23514370458123643,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2898678965","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9777542,0.00018271344,0.016929919,0.00004511792,0.0009803683,0.00041320614,0.00004155221,0.00027913562,0.003373837],"genre_scores_gemma":[0.7964491,0.00008478171,0.20247434,0.000044645894,0.0000212813,0.00001676959,0.000013802994,0.00005700598,0.00083823485],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9987752,0.000016621045,0.00021397995,0.00024982812,0.0002551933,0.00048921653],"domain_scores_gemma":[0.9992559,0.00017609386,0.000022429767,0.0003214142,0.00010801275,0.00011616838],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00027300365,0.00017511922,0.0002100587,0.000053946234,0.00018515017,0.000060682534,0.00017887892,0.00018155061,0.00012581718],"category_scores_gemma":[0.000114282186,0.00016885278,0.00006891389,0.00020644891,0.000088239874,0.000092602735,0.00003645516,0.00016966625,0.00039818496],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00009813856,0.000027741336,0.00012841591,0.000062516694,0.000050202827,0.000007647341,0.00051092653,0.0073656407,0.9586391,0.000046505233,0.018465186,0.014598005],"study_design_scores_gemma":[0.0006275788,0.00011016593,0.000106397754,0.000030541545,0.000008514033,0.0000068265626,0.00003709311,0.37981355,0.5294446,0.00030719145,0.08928207,0.00022547484],"about_ca_topic_score_codex":0.000021251464,"about_ca_topic_score_gemma":0.000050666535,"teacher_disagreement_score":0.4291945,"about_ca_system_score_codex":0.00011767534,"about_ca_system_score_gemma":0.000048008078,"threshold_uncertainty_score":0.6885617},"labels":[],"label_agreement":null},{"id":"W2918697859","doi":"10.1515/nanoph-2018-0202","title":"Laser‐written colours on silver: optical effect of alumina coating","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Laser Material Processing Techniques","field":"Engineering","cited_by":12,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Carleton University; University of Ottawa","funders":"Canada Research Chairs; University of Ottawa","keywords":"Materials science; Laser; Hue; Coating; Deposition (geology); Optics; Colour difference; Radiometric dating; Radiation; Structural coloration; Layer (electronics); Optoelectronics; Nanotechnology; Photonic crystal; Geology; Remote sensing; Physics","score_opus":0.005430495637813749,"score_gpt":0.23277148510307236,"score_spread":0.2273409894652586,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2918697859","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99026066,0.00002929798,0.00011920794,0.000015105575,0.00040865832,0.00020448373,0.000010863543,0.0006244537,0.008327267],"genre_scores_gemma":[0.9921091,0.00001230266,0.0076536136,0.00004072133,0.00006071916,0.000024599265,0.0000050641793,0.000051499475,0.000042376436],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99912196,0.000029149984,0.00022611338,0.00016824,0.00019635969,0.0002581679],"domain_scores_gemma":[0.9994291,0.00012531642,0.000045381057,0.00028045138,0.00005964009,0.000060118917],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00030395458,0.00017511865,0.00027188243,0.000048367117,0.00005180121,0.000029675535,0.00021797499,0.00015670135,0.00004858482],"category_scores_gemma":[0.00010595333,0.00015638823,0.000050403276,0.00015485618,0.00012139932,0.000066094326,0.000051640127,0.0001359775,0.000064316264],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00014593004,0.0000502848,0.000382231,0.00047016522,0.000046375557,0.000019158908,0.00018717801,0.00027192698,0.9870779,0.000273056,0.0042526852,0.006823143],"study_design_scores_gemma":[0.00030385776,0.000932915,0.00006449273,0.0001392902,0.00002302976,0.000004172366,0.000004749722,0.019848075,0.9769037,0.00009104427,0.001527705,0.00015696468],"about_ca_topic_score_codex":0.000010331704,"about_ca_topic_score_gemma":0.000004133238,"teacher_disagreement_score":0.019576147,"about_ca_system_score_codex":0.000077759825,"about_ca_system_score_gemma":0.000021748756,"threshold_uncertainty_score":0.6377327},"labels":[],"label_agreement":null},{"id":"W2922188453","doi":"10.1515/nanoph-2018-0230","title":"Topological plasmonic edge states in a planar array of metallic nanoparticles","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Topological Materials and Phenomena","field":"Physics and Astronomy","cited_by":54,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Waterloo","funders":"","keywords":"Plasmon; Nanophotonics; Planar; Photonics; Topology (electrical circuits); Plasmonic nanoparticles; Lattice (music); Materials science; Optoelectronics; Miniaturization; Physics; Nanotechnology; Computer science; Mathematics","score_opus":0.015620809112557059,"score_gpt":0.2516429138474587,"score_spread":0.23602210473490162,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2922188453","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99544793,0.0000899045,0.00004228715,0.00009740714,0.00018889269,0.0001461607,0.00006167435,0.000019710835,0.003906055],"genre_scores_gemma":[0.99832743,0.000012709764,0.0014167927,0.000065875494,0.00006013944,0.000016299331,0.000011456017,0.000010040961,0.00007924861],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9989368,0.000062796455,0.00033725234,0.00022866682,0.00010775621,0.0003267506],"domain_scores_gemma":[0.99950635,0.00008138281,0.00010697951,0.0001999831,0.00003744072,0.00006783381],"candidate_categories":["insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.0001757994,0.00014344919,0.00031588643,0.00003166311,0.000052772157,0.000021012436,0.00019478434,0.0000597855,0.0018626979],"category_scores_gemma":[0.000009160997,0.00010730512,0.0000669705,0.00016601499,0.00023633403,0.000053627384,0.000038924834,0.00009021551,0.00007727731],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00013069077,0.00038892572,0.019016821,0.000015207092,0.00004322973,0.0000029110115,0.0005566156,0.000012677509,0.7894551,0.18991472,0.000042270913,0.00042082288],"study_design_scores_gemma":[0.00060181785,0.00046439652,0.0046591284,0.00001697843,0.000014926496,6.986838e-7,0.00028193445,0.00010896828,0.84061784,0.1489161,0.0041243746,0.00019283804],"about_ca_topic_score_codex":0.00025350577,"about_ca_topic_score_gemma":0.000029180777,"teacher_disagreement_score":0.05116273,"about_ca_system_score_codex":0.000017289902,"about_ca_system_score_gemma":0.000038423972,"threshold_uncertainty_score":0.9990497},"labels":[],"label_agreement":null},{"id":"W2982122447","doi":"10.1515/nanoph-2019-0343","title":"Comprehensive insights into intracellular fate of WS <sub>2</sub> nanosheets for enhanced photothermal therapeutic outcomes via exocytosis inhibition","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Nanoplatforms for cancer theranostics","field":"Engineering","cited_by":19,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"McGill University","funders":"Science, Technology and Innovation Commission of Shenzhen Municipality; National Natural Science Foundation of China; METAvivor; Brigham and Women's Hospital","keywords":"Photothermal therapy; Endocytosis; Exocytosis; Pinocytosis; Nanotechnology; Intracellular; Cancer cell; Receptor-mediated endocytosis; Photothermal effect; Lysosome; Drug delivery; Cell biology; Biophysics; Chemistry; Materials science; Secretion; Cancer; Biology; Cell; Biochemistry","score_opus":0.01049300699675744,"score_gpt":0.22320451374394248,"score_spread":0.21271150674718503,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2982122447","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9585561,0.0015350924,0.03700318,0.000015384407,0.0012796851,0.0011672868,0.000037961054,0.00028776532,0.00011755656],"genre_scores_gemma":[0.993788,0.00041794093,0.0050162724,0.00026433656,0.000083050974,0.00020255818,0.00004332411,0.0001729978,0.000011493659],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9979317,0.000027438678,0.00071045617,0.00040699393,0.0003690136,0.00055439444],"domain_scores_gemma":[0.9985114,0.00019624557,0.00019613263,0.00057754456,0.00039393417,0.0001247679],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.000105038205,0.00049240544,0.0006942402,0.00019242558,0.00016649526,0.000036492773,0.00027675251,0.00035897587,0.00003293682],"category_scores_gemma":[0.000021439928,0.00046854833,0.0002765805,0.00040367118,0.00023008656,0.00028035397,0.000055787008,0.00022035469,0.000059934442],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000159004,0.00006892961,0.000022492872,0.00029385992,0.00023076728,0.000002426738,0.0015771277,0.0011438968,0.99044627,0.0000795351,0.00003749788,0.0059382063],"study_design_scores_gemma":[0.0018310774,0.00043077493,0.00010547977,0.00009819097,0.00009738497,0.0000036459196,0.00006776277,0.022250144,0.96837145,0.0020933475,0.004140487,0.0005102429],"about_ca_topic_score_codex":0.000017644752,"about_ca_topic_score_gemma":0.00006025787,"teacher_disagreement_score":0.035231937,"about_ca_system_score_codex":0.0002918419,"about_ca_system_score_gemma":0.00007741054,"threshold_uncertainty_score":0.9997766},"labels":[],"label_agreement":null},{"id":"W2990016752","doi":"10.1515/nanoph-2019-0385","title":"Helium focused ion beam direct milling of plasmonic heptamer‐arranged nanohole arrays","year":2019,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasma Diagnostics and Applications","field":"Engineering","cited_by":36,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Ottawa","funders":"","keywords":"Materials science; Focused ion beam; Plasmon; Beam (structure); Fabrication; Ion milling machine; Optics; Optoelectronics; Ion beam; Ion; Nanotechnology; Chemistry; Layer (electronics)","score_opus":0.005502013239676921,"score_gpt":0.18209660769572092,"score_spread":0.176594594456044,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2990016752","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9911505,0.0005190324,0.00014974992,0.00003759678,0.0006145224,0.0003788457,0.00009767482,0.00019274298,0.006859363],"genre_scores_gemma":[0.99565643,0.0007006879,0.0032626216,0.000029333454,0.000023133269,0.00006232386,0.00003586229,0.000058068665,0.00017153443],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99894243,0.0000094805955,0.00030521952,0.00022839308,0.0002063853,0.00030811122],"domain_scores_gemma":[0.9991757,0.00018081394,0.00006803386,0.00043485768,0.000060112267,0.00008043298],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00012254718,0.00018807742,0.0003037692,0.000074216085,0.000049867438,0.000021465623,0.00022899022,0.00014621158,0.000052851567],"category_scores_gemma":[0.0000322591,0.00019923276,0.000113195245,0.00030497502,0.000026496884,0.000063326086,0.000029608851,0.00017883579,0.00027943533],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000008636876,0.00006237783,0.00040724335,0.00010304985,0.000052059593,0.0000015936615,0.00017812355,0.08608289,0.9116415,0.00022719338,0.00060327235,0.00063210126],"study_design_scores_gemma":[0.0004672625,0.000053923366,0.00018005549,0.00007164435,0.000025085703,0.0000015143838,0.000026060248,0.100222975,0.8763203,0.00008887089,0.022315737,0.00022654884],"about_ca_topic_score_codex":0.000019776575,"about_ca_topic_score_gemma":0.000019921574,"teacher_disagreement_score":0.035321135,"about_ca_system_score_codex":0.00006844854,"about_ca_system_score_gemma":0.00003918229,"threshold_uncertainty_score":0.8124476},"labels":[],"label_agreement":null},{"id":"W2990495882","doi":"10.1515/nanoph-2019-0418","title":"Simply synthesized nitrogen‐doped graphene quantum dot (NGQD)‐modified electrode for the ultrasensitive photoelectrochemical detection of dopamine","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Carbon and Quantum Dots Applications","field":"Materials Science","cited_by":56,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Toronto","funders":"","keywords":"Quantum dot; Photocurrent; Graphene quantum dot; Graphene; Materials science; Electrode; Photoelectrochemistry; Nanomaterials; Nanotechnology; Optoelectronics; Semiconductor; Detection limit; Chemistry; Electrochemistry","score_opus":0.013805367263533356,"score_gpt":0.25591123322917286,"score_spread":0.24210586596563952,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2990495882","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.97985774,0.00019662466,0.018045643,0.00018523519,0.00024471804,0.0011173706,0.00009035533,0.0001242202,0.00013808167],"genre_scores_gemma":[0.9979541,0.00012919982,0.0010839097,0.00024748474,0.00011898244,0.0003686638,0.000016428394,0.000043557833,0.000037699167],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9981194,0.000078692334,0.00047731787,0.00048152686,0.0003150474,0.0005279801],"domain_scores_gemma":[0.9977069,0.00084620377,0.00028748985,0.00060996745,0.000454287,0.00009513648],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.0006012731,0.00024664134,0.00037494765,0.00007181625,0.00035141266,0.000049463597,0.00036411965,0.0001525257,0.00006730722],"category_scores_gemma":[0.00034711917,0.00018572742,0.00021452621,0.0004746237,0.00040181505,0.000067500405,0.000042910822,0.00015363969,0.000028015387],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00078256265,0.00010683451,0.0000030951542,0.0000160596,0.000033775395,3.7365885e-7,0.00012640214,0.0000059584363,0.9958966,0.0024677168,0.00009336912,0.00046726185],"study_design_scores_gemma":[0.00082888704,0.000416428,0.000024460793,0.000011254609,0.00012344438,0.000024789388,0.00009483539,0.0211847,0.97268915,0.0021469947,0.0022371984,0.00021785038],"about_ca_topic_score_codex":0.0003075225,"about_ca_topic_score_gemma":0.00027599288,"teacher_disagreement_score":0.023207434,"about_ca_system_score_codex":0.00009059154,"about_ca_system_score_gemma":0.00015670796,"threshold_uncertainty_score":0.75737447},"labels":[],"label_agreement":null},{"id":"W2990639814","doi":"10.1515/nanoph-2019-0368","title":"Implementation of on‐chip multi‐channel focusing wavelength demultiplexer with regularized digital metamaterials","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":92,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Wuhan National Laboratory for Optoelectronics; Natural Science Foundation of Hunan Province; China Postdoctoral Science Foundation; National University of Defense Technology; National Natural Science Foundation of China; National Supercomputing Center, Korea Institute of Science and Technology Information; College of Family Physicians of Canada; National Supercomputer Centre in Guangzhou","keywords":"Demultiplexer; Splitter; Metamaterial; Materials science; Photonic integrated circuit; Photonics; Optoelectronics; Optics; Computer science; Multiplexer; Electronic engineering; Physics; Telecommunications; Multiplexing; Engineering","score_opus":0.01536368890073897,"score_gpt":0.2506752526537405,"score_spread":0.23531156375300155,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2990639814","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9957939,0.00005067948,0.0019193763,0.000013859068,0.00027661104,0.0003465034,0.00008629428,0.00015295311,0.0013598508],"genre_scores_gemma":[0.98773974,0.000028385773,0.012004577,0.000043015545,0.000042294723,0.000024719735,0.000023347246,0.0000522342,0.000041664283],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9988346,0.000017023829,0.00035344737,0.00022096942,0.00024127545,0.00033269988],"domain_scores_gemma":[0.9993856,0.00006188006,0.00008417219,0.0002760433,0.00010709956,0.0000852345],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00014572515,0.000218414,0.0003282535,0.0000650025,0.000065754575,0.00006612925,0.00015247359,0.00010027113,0.00010625974],"category_scores_gemma":[0.000022694669,0.0001736182,0.00006465172,0.00017263269,0.00009903454,0.00022227778,0.00003365812,0.000086243934,0.000040797437],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0007295898,0.00031857294,0.0006417804,0.0004907211,0.0008931146,0.000027003383,0.0034564869,0.0022557497,0.9741694,0.0033628715,0.00015380408,0.01350093],"study_design_scores_gemma":[0.002018737,0.00030305848,0.0011558342,0.00007782597,0.000060329843,0.0000063431467,0.00028836352,0.12067665,0.873788,0.00011924426,0.0011975862,0.00030802484],"about_ca_topic_score_codex":0.00003079226,"about_ca_topic_score_gemma":0.00006571147,"teacher_disagreement_score":0.11842091,"about_ca_system_score_codex":0.000060579332,"about_ca_system_score_gemma":0.0000415381,"threshold_uncertainty_score":0.7079945},"labels":[],"label_agreement":null},{"id":"W2993560607","doi":"10.1515/nanoph-2019-0239","title":"Beyond dipolar Huygens’ metasurfaces for full‐phase coverage and unity transmittance","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":45,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Ottawa","funders":"Deutsche Forschungsgemeinschaft; Alexander von Humboldt-Stiftung","keywords":"Dipole; Optics; Physics; Wavelength; Symmetry (geometry); Phase (matter); Transmittance; Rotational symmetry; Duality (order theory); Huygens–Fresnel principle; Geometry; Quantum mechanics","score_opus":0.021422078136656312,"score_gpt":0.29698913410935635,"score_spread":0.27556705597270004,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2993560607","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.98976356,0.0020092432,0.0051111216,0.00014398723,0.00068167684,0.00082477974,0.00089829584,0.000083607105,0.0004837563],"genre_scores_gemma":[0.9161636,0.000523587,0.08223176,0.00034691385,0.00007127254,0.00018175565,0.000034151624,0.000039898114,0.00040701104],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9984186,0.00008868791,0.0003879462,0.0004843376,0.00022532433,0.00039506648],"domain_scores_gemma":[0.99882567,0.00013415706,0.00017893923,0.0004903465,0.00020839523,0.00016251074],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.0011040439,0.0002210963,0.0003913594,0.000031064345,0.0005042195,0.00014939216,0.00028368057,0.00011467254,0.0005865034],"category_scores_gemma":[0.00008997781,0.00019120911,0.0000717554,0.00017297824,0.00026223552,0.00014039165,0.00004820666,0.00006368415,0.00012039748],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00012535391,0.00009412919,0.000008834001,0.00005192532,0.000016906773,6.320688e-7,0.00026741595,0.000010839479,0.9955371,0.0027421513,0.0003589082,0.0007857832],"study_design_scores_gemma":[0.001076593,0.0003025165,0.000033254964,0.000010157465,0.00009277758,0.0000052490313,0.000026198657,0.0012906311,0.8165009,0.003170881,0.17727804,0.00021277281],"about_ca_topic_score_codex":0.000040468723,"about_ca_topic_score_gemma":0.00006975414,"teacher_disagreement_score":0.17903619,"about_ca_system_score_codex":0.000024299326,"about_ca_system_score_gemma":0.00008331012,"threshold_uncertainty_score":0.7797281},"labels":[],"label_agreement":null},{"id":"W2999110576","doi":"10.1515/nanoph-2019-0459","title":"Improving nanoscale terahertz field localization by means of sharply tapered resonant nanoantennas","year":2020,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":9,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut National de la Recherche Scientifique","funders":"Fonds de recherche du Québec – Nature et technologies; Natural Sciences and Engineering Research Council of Canada","keywords":"Terahertz radiation; Tapering; Resonator; Nanoscopic scale; Optoelectronics; Field (mathematics); Plasmon; Wavelength; Nanostructure; Materials science; Optics; Quantum; Physics; Nanotechnology","score_opus":0.010681203120179046,"score_gpt":0.20917338284863424,"score_spread":0.1984921797284552,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W2999110576","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9262381,0.007994669,0.058141466,0.0012297556,0.00064197456,0.0008716657,0.00033353592,0.0006971096,0.0038516752],"genre_scores_gemma":[0.9922271,0.0011368123,0.005678502,0.0003788501,0.000007923986,0.000024021034,0.00004912941,0.000070741946,0.0004269278],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9985326,0.000029549903,0.0003768998,0.00027312656,0.00038356028,0.0004042921],"domain_scores_gemma":[0.9993225,0.0001224271,0.000051044455,0.00023609809,0.000083271225,0.00018470461],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00013527952,0.00019877525,0.00030173358,0.000038454302,0.00006536321,0.000034635734,0.00031560208,0.00020427274,0.00019479293],"category_scores_gemma":[0.0001767294,0.00019283836,0.000089725145,0.0003649225,0.000052445746,0.00012347032,0.00007334775,0.00027724827,0.00004277341],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00010549337,0.0000519822,0.0011061713,0.00037216124,0.000057584788,0.00002286886,0.00080423115,0.0064964383,0.9452335,0.0000565243,0.0380958,0.007597215],"study_design_scores_gemma":[0.00032750852,0.00010095134,0.000013153699,0.000028637613,0.000008138989,0.0000016231025,0.000092772054,0.65347373,0.30283228,0.000004836401,0.042966843,0.00014953157],"about_ca_topic_score_codex":0.000088285255,"about_ca_topic_score_gemma":0.000030139836,"teacher_disagreement_score":0.6469773,"about_ca_system_score_codex":0.000058284433,"about_ca_system_score_gemma":0.00007042183,"threshold_uncertainty_score":0.78637195},"labels":[],"label_agreement":null},{"id":"W3004887703","doi":"10.1515/nanoph-2019-0532","title":"Proceedings of the 9th International Conference on Surface Plasmon Photonics (SPP9)","year":2020,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":2,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Ottawa","funders":"Novo Nordisk Fonden; Fonds National de la Recherche Luxembourg; Danmarks Grundforskningsfond; Villum Fonden","keywords":"Photonics; Nanomaterials; Surface plasmon; Nanotechnology; Plasmon; Materials science; Engineering physics; Optoelectronics; Physics","score_opus":0.03005446948680052,"score_gpt":0.23897310683550047,"score_spread":0.20891863734869995,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3004887703","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9369116,0.00007344164,0.000012616135,0.00088925107,0.0009410141,0.00027147346,0.0000767891,0.00013541395,0.060688403],"genre_scores_gemma":[0.9946271,0.00056160655,0.0034989975,0.00018159644,0.0000045095717,0.00000964434,0.0000045985953,0.000038461083,0.0010734942],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99855983,0.000008066061,0.00027166246,0.00024009551,0.00061429763,0.00030607078],"domain_scores_gemma":[0.99943656,0.000059599486,0.00006321156,0.0001517336,0.00016163818,0.00012727975],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00014457581,0.00019264554,0.00022925116,0.00002370306,0.000059308903,0.000052497315,0.00074826577,0.00014413458,0.00021361712],"category_scores_gemma":[0.000083901636,0.0001521687,0.00010085465,0.00032572675,0.000082293984,0.000099958204,0.00012704439,0.00050804036,0.00008468106],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0003540788,0.0001666162,0.00481754,0.00038013002,0.00029966806,0.000016231386,0.0024150994,0.21552004,0.70951426,0.014545917,0.05163323,0.00033718202],"study_design_scores_gemma":[0.0003667529,0.00006378588,0.00008120361,0.00004413753,0.000006945532,0.0000033653769,0.00019344896,0.7426029,0.23204696,0.000073411116,0.024371395,0.00014568269],"about_ca_topic_score_codex":0.000004982575,"about_ca_topic_score_gemma":0.0000035687974,"teacher_disagreement_score":0.52708286,"about_ca_system_score_codex":0.00009615296,"about_ca_system_score_gemma":0.00010146361,"threshold_uncertainty_score":0.62052596},"labels":[],"label_agreement":null},{"id":"W3015065504","doi":"10.1515/nanoph-2019-0556","title":"MXenes: focus on optical and electronic properties and corresponding applications","year":2020,"lang":"en","type":"article","venue":"Nanophotonics","topic":"MXene and MAX Phase Materials","field":"Materials Science","cited_by":162,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of British Columbia","funders":"","keywords":"MXenes; Carbide; Materials science; Nanotechnology; Graphene; Nanomaterials; Electronics; Nitride; Characterization (materials science); Engineering physics; Chemistry; Layer (electronics); Physics; Metallurgy; Physical chemistry","score_opus":0.03017653160671991,"score_gpt":0.2379251784460037,"score_spread":0.2077486468392838,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3015065504","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.996586,0.0007591638,0.00023536208,0.00095149374,0.000063477295,0.00039188814,0.000013916045,0.000086070024,0.0009126119],"genre_scores_gemma":[0.9978637,0.00025252756,0.00089532643,0.00071969425,0.000049549275,0.00011799156,0.0000021083497,0.00001676725,0.00008234591],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99907136,0.00003305643,0.0001705346,0.0003255492,0.000131745,0.00026777879],"domain_scores_gemma":[0.99960697,0.000047125133,0.0000466527,0.00014608077,0.000025215239,0.00012798744],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00017613746,0.00012496595,0.00018600785,0.000022983739,0.00013625258,0.00013335382,0.000108709406,0.00006383396,0.00011144152],"category_scores_gemma":[0.000058094403,0.00010041151,0.000016647768,0.0000875908,0.00008512449,0.00008357433,0.00009198258,0.00007211148,0.00009401513],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00012332894,0.00001958009,0.000010115009,0.00004059778,0.0000032101646,0.0000025627623,0.00021581714,0.000005122865,0.98458433,0.013767218,0.00008626767,0.0011418624],"study_design_scores_gemma":[0.00034541436,0.00029095457,0.000017674683,0.00001698813,0.00001793433,0.000012131212,0.00007065509,0.00052884646,0.96781194,0.00090166053,0.029836986,0.00014883681],"about_ca_topic_score_codex":0.0000098485525,"about_ca_topic_score_gemma":0.000003451915,"teacher_disagreement_score":0.029750718,"about_ca_system_score_codex":0.000024166338,"about_ca_system_score_gemma":0.00007547492,"threshold_uncertainty_score":0.40946624},"labels":[],"label_agreement":null},{"id":"W3016618682","doi":"10.1515/nanoph-2020-0229","title":"Temporal plasmonics: Fano and Rabi regimes in the time domain in metal nanostructures","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":27,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut National de la Recherche Scientifique","funders":"National Key Research and Development Program of China; Higher Education Discipline Innovation Project; University of Electronic Science and Technology of China; China Postdoctoral Science Foundation","keywords":"Plasmon; Fano resonance; Fano plane; Quantum decoherence; Rabi cycle; Time evolution; Relaxation (psychology)","score_opus":0.007755343744538509,"score_gpt":0.22651372108347118,"score_spread":0.21875837733893266,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3016618682","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.98953027,0.0012160605,0.0000057048046,0.0001785649,0.00016259991,0.00032801324,0.000022024258,0.0000698181,0.008486919],"genre_scores_gemma":[0.9940051,0.00026590558,0.0051475572,0.00009202835,0.0000071673257,0.000032280903,0.000010722229,0.000034798715,0.00040447753],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9984123,0.00010939735,0.00030268537,0.00028049963,0.00035208743,0.0005430343],"domain_scores_gemma":[0.9993112,0.00022556707,0.000028158904,0.00033808037,0.00002607839,0.00007091771],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00072866504,0.00023007928,0.00030052123,0.00015582955,0.00008147126,0.00007569012,0.0003928725,0.00021301465,0.00009158777],"category_scores_gemma":[0.00006559308,0.00017256345,0.000047934416,0.00046900436,0.00021315954,0.00013979917,0.00007776889,0.0004797865,0.000093837654],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.001853809,0.001002604,0.20259419,0.0012124102,0.0010189641,0.003456277,0.06809566,0.034223817,0.5725205,0.017604243,0.08172598,0.014691521],"study_design_scores_gemma":[0.005990789,0.00067744753,0.032881297,0.00023903136,0.00003942752,0.00026605875,0.002935842,0.67507946,0.077463225,0.011267022,0.19135363,0.0018067454],"about_ca_topic_score_codex":0.00007929853,"about_ca_topic_score_gemma":0.0004891776,"teacher_disagreement_score":0.64085567,"about_ca_system_score_codex":0.00008840751,"about_ca_system_score_gemma":0.000076829994,"threshold_uncertainty_score":0.70369333},"labels":[],"label_agreement":null},{"id":"W3033290616","doi":"10.1515/nanoph-2020-0040","title":"On‐chip scalable mode‐selective converter based on asymmetrical micro‐racetrack resonators","year":2020,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":6,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Fundamental Research Funds for the Central Universities; RMIT University; Ontario Ministry of Natural Resources and Forestry; State Key Laboratory on Integrated Optoelectronics; Australian National Fabrication Facility","keywords":"Reconfigurability; Resonator; Multiplexing; Optoelectronics; Scalability; Materials science; Photonics; Chip; Electronic engineering; Waveguide; Coupled mode theory; Computer science; Engineering; Telecommunications; Refractive index","score_opus":0.010743804851690639,"score_gpt":0.21846433348041686,"score_spread":0.20772052862872623,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3033290616","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.83323467,0.0008288768,0.0029519254,0.0012584579,0.0009650581,0.00093049265,0.00017723332,0.001220193,0.1584331],"genre_scores_gemma":[0.991638,0.000052937976,0.0025441335,0.0055214153,0.000039201994,0.000032024094,0.000015261057,0.000079751495,0.0000772833],"study_design_codex":"simulation_or_modeling","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9982418,0.00004026609,0.00029081706,0.00045601177,0.00043096425,0.00054017105],"domain_scores_gemma":[0.9988096,0.00041623702,0.000035040757,0.00031151462,0.000063049134,0.00036459716],"candidate_categories":["metaepi_narrow","insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.000107558175,0.00033822202,0.00039199894,0.00010936932,0.00008536346,0.00006086405,0.00031780216,0.00028148707,0.0002443726],"category_scores_gemma":[0.00021253535,0.0003033464,0.00015882275,0.0008479731,0.000057044297,0.00008715305,0.000031694017,0.00070632424,0.00092177227],"study_design_candidate":"simulation_or_modeling","study_design_consensus":"simulation_or_modeling","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.005012159,0.0030041977,0.003796948,0.0020220939,0.0013170193,0.00095591915,0.0031572513,0.569682,0.11000614,0.07399969,0.206497,0.020549554],"study_design_scores_gemma":[0.0008661303,0.00036459102,0.00022847157,0.000037072117,0.000023220806,0.0000013891828,0.000012893264,0.88106245,0.097009465,0.0003113484,0.0197349,0.00034806665],"about_ca_topic_score_codex":0.000011298815,"about_ca_topic_score_gemma":0.0000035702747,"teacher_disagreement_score":0.31138042,"about_ca_system_score_codex":0.00022065562,"about_ca_system_score_gemma":0.00008940094,"threshold_uncertainty_score":0.9999419},"labels":[],"label_agreement":null},{"id":"W3037608599","doi":"10.1515/nanoph-2020-0056","title":"Optically and radio frequency (RF) transparent meta‐glass","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":17,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Toronto","funders":"Natural Sciences and Engineering Research Council of Canada; University of Toronto; CMC Microsystems","keywords":"Materials science; Radio frequency; Optoelectronics; Transmittance; Dielectric; Opacity; Indium tin oxide; Electrical conductor; Metamaterial; Transparency (behavior); Refractive index; Optics; Thin film; Composite material; Nanotechnology; Computer science; Telecommunications","score_opus":0.05234402013012789,"score_gpt":0.28721278153598534,"score_spread":0.23486876140585744,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3037608599","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9939537,0.0016675969,0.001132398,0.00030335356,0.00059658434,0.00034279018,0.000093016984,0.00009276853,0.0018177637],"genre_scores_gemma":[0.90621644,0.00048292615,0.09263341,0.00021634967,0.00007247111,0.00013275929,0.000007824044,0.000026044081,0.00021178693],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9985258,0.000066848224,0.00036986425,0.0004363067,0.00025873235,0.0003424348],"domain_scores_gemma":[0.99905163,0.000057772955,0.00010415128,0.00048658616,0.0001247148,0.00017513566],"candidate_categories":["insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.000667638,0.00019215049,0.00041444338,0.00002704443,0.00023148826,0.00012629858,0.000283149,0.00009973817,0.0026297595],"category_scores_gemma":[0.000044617755,0.00014634924,0.00008314744,0.0001338171,0.0002673748,0.00012663759,0.0000484705,0.00006222348,0.0004360345],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000011467682,0.00003965596,0.00003435112,0.000018966797,0.000053213935,0.0000017476375,0.00016211529,0.0000032262699,0.994903,0.0045389966,0.000115347626,0.00011786552],"study_design_scores_gemma":[0.00031403327,0.00014491218,0.0005957381,0.0000075905264,0.0005311913,0.000017444372,0.000021501823,0.00025034908,0.96608126,0.0014947322,0.030311838,0.0002293973],"about_ca_topic_score_codex":0.00007642913,"about_ca_topic_score_gemma":0.00005254574,"teacher_disagreement_score":0.09150102,"about_ca_system_score_codex":0.000024974786,"about_ca_system_score_gemma":0.00007593666,"threshold_uncertainty_score":0.99828196},"labels":[],"label_agreement":null},{"id":"W3038014797","doi":"10.1515/nanoph-2020-0213","title":"Enhanced two‐photon photoluminescence assisted by multi‐resonant characteristics of a gold nanocylinder","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Gold and Silver Nanoparticles Synthesis and Applications","field":"Materials Science","cited_by":11,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut interdisciplinaire d'innovation technologique; Université de Sherbrooke","funders":"Baden-Württemberg Stiftung","keywords":"Photoluminescence; Plasmon; Materials science; Optoelectronics; Nanorod; Quantum dot; Dipole; Nanoclusters; Excitation; Photoluminescence excitation; Spontaneous emission; Molecular physics; Optics; Nanotechnology; Physics; Laser","score_opus":0.018331571244564894,"score_gpt":0.26552103803466,"score_spread":0.2471894667900951,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3038014797","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99770373,0.0001108781,0.00057011156,0.00004580237,0.00035053035,0.00038291595,0.00033036823,0.00008531819,0.00042032413],"genre_scores_gemma":[0.9927527,0.00006753229,0.006057841,0.00019825397,0.00004566826,0.00009822887,0.000024674473,0.00003153551,0.0007236066],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99792624,0.00006475996,0.00064725324,0.0005136005,0.00036467594,0.00048348942],"domain_scores_gemma":[0.99843156,0.00009575303,0.00037344836,0.00061510695,0.00032688305,0.00015721854],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00035080628,0.00024745252,0.00042848062,0.000042473086,0.00017496182,0.00006801538,0.00048164942,0.00012941581,0.00043008398],"category_scores_gemma":[0.00009942636,0.00021515915,0.000113530026,0.00033612314,0.0003652586,0.00011955386,0.000104568884,0.000098073106,0.00043901507],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00005876149,0.00039887062,0.00022508197,0.000023126253,0.000007756414,0.0000015011465,0.00024786097,1.6229984e-7,0.9953325,0.00020116297,0.00073557865,0.002767679],"study_design_scores_gemma":[0.0007277865,0.0001148062,0.0015348177,0.00006904945,0.000031279236,0.000005074592,0.000050006915,0.0020652898,0.98507166,0.00001631924,0.010049092,0.00026480158],"about_ca_topic_score_codex":0.00014971028,"about_ca_topic_score_gemma":0.0000473353,"teacher_disagreement_score":0.010260781,"about_ca_system_score_codex":0.000055858978,"about_ca_system_score_gemma":0.00012368706,"threshold_uncertainty_score":0.87739354},"labels":[],"label_agreement":null},{"id":"W3038052564","doi":"10.1515/nanoph-2020-0171","title":"Boolean learning under noise‐perturbations in hardware neural networks","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Neural Networks and Reservoir Computing","field":"Computer Science","cited_by":14,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"H2020 Marie Skłodowska-Curie Actions; European Commission; Agence Nationale de la Recherche; Volkswagen Foundation; Ottawa Hospital Research Institute","keywords":"Artificial neural network; Computer science; Noise (video); Path (computing); Convergence (economics); Focus (optics); Artificial intelligence; Computer engineering; Computer network","score_opus":0.013772320494903118,"score_gpt":0.24067665718903478,"score_spread":0.22690433669413165,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3038052564","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.63290036,0.0010237829,0.35661536,0.0022490912,0.0027895193,0.00038005284,6.7861026e-7,0.00053411414,0.0035070418],"genre_scores_gemma":[0.98873496,0.000043269312,0.009295305,0.0010838467,0.00023664856,0.000007905147,0.0000032910198,0.000019831772,0.0005749677],"study_design_codex":"simulation_or_modeling","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9983302,0.00010924538,0.0002915783,0.0004706026,0.00024023718,0.00055816857],"domain_scores_gemma":[0.99907464,0.00014334287,0.00010010115,0.0004589515,0.000108957036,0.000113982445],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00023222095,0.00018093063,0.00018968602,0.00008726197,0.00037364327,0.00023425724,0.0008433626,0.0001254846,0.00002173489],"category_scores_gemma":[0.00003959862,0.00016100008,0.00008234119,0.00084957987,0.000071556526,0.00031076279,0.00047479046,0.00052932184,0.000029512432],"study_design_candidate":"simulation_or_modeling","study_design_consensus":"simulation_or_modeling","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000014180169,0.00006054188,0.003598979,0.000007852035,0.0000128234815,0.000044961856,0.0004941971,0.9698895,0.000879366,0.0057570045,0.0009491468,0.018291397],"study_design_scores_gemma":[0.0002574274,0.00014536704,0.0025371322,0.000034272707,0.0000023048985,0.000020225443,0.00002550608,0.98962647,0.00014269253,0.0003547824,0.006649702,0.00020412175],"about_ca_topic_score_codex":0.000043549637,"about_ca_topic_score_gemma":0.00010551382,"teacher_disagreement_score":0.3558346,"about_ca_system_score_codex":0.00007009438,"about_ca_system_score_gemma":0.000042732274,"threshold_uncertainty_score":0.65653926},"labels":[],"label_agreement":null},{"id":"W3039902903","doi":"10.1515/nanoph-2020-0049","title":"Robust optical physical unclonable function using disordered photonic integrated circuits","year":2020,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Physical Unclonable Functions (PUFs) and Hardware Security","field":"Computer Science","cited_by":42,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Natural Sciences and Engineering Research Council of Canada; Air Force Office of Scientific Research; Clemson University","keywords":"Physical unclonable function; Photonics; Robustness (evolution); Polarization (electrochemistry); Interferometry; Optoelectronics; Materials science; Computer science; Nanotechnology; Physics; Optics; Cryptography","score_opus":0.04232727221953289,"score_gpt":0.23154861519956654,"score_spread":0.18922134298003365,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3039902903","genre_codex":"methods","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":null,"domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.39156377,0.00036863197,0.6006863,0.0008970627,0.0011148023,0.0006310672,0.000034067314,0.00097332837,0.0037309395],"genre_scores_gemma":[0.98771,0.000023808994,0.010611341,0.001220267,0.00020596855,0.000038054826,0.0000377081,0.000045560217,0.00010729603],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99704134,0.000104272774,0.00038759346,0.0010493142,0.0006602264,0.00075727614],"domain_scores_gemma":[0.9982137,0.0001299677,0.00013869231,0.00074583647,0.00030294436,0.00046887557],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00016931978,0.0004167711,0.00053364126,0.000079990634,0.0004155941,0.00031693577,0.0009852889,0.00019594785,0.00008370046],"category_scores_gemma":[0.0001702663,0.00039265622,0.00028932124,0.0020273281,0.00012163353,0.0009003662,0.0004469512,0.0007171309,0.0002873608],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00043067677,0.0041205753,0.000340287,0.00038222026,0.00068465853,0.00023171795,0.0048948457,0.064880796,0.4627496,0.41181037,0.0053884555,0.044085797],"study_design_scores_gemma":[0.0008770655,0.0004981875,0.00012311772,0.000029002293,0.0000934473,0.000014210338,0.0000898183,0.95286155,0.012184911,0.005616439,0.027060976,0.00055127783],"about_ca_topic_score_codex":0.000084778156,"about_ca_topic_score_gemma":0.000014319368,"teacher_disagreement_score":0.88798076,"about_ca_system_score_codex":0.00021590827,"about_ca_system_score_gemma":0.0005828201,"threshold_uncertainty_score":0.99985254},"labels":[],"label_agreement":null},{"id":"W3041849462","doi":"10.1515/nanoph-2020-0239","title":"Tunable photoluminescence properties of selenium nanoparticles: biogenic versus chemogenic synthesis","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Selenium in Biological Systems","field":"Nursing","cited_by":30,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Calgary","funders":"Natural Sciences and Engineering Research Council of Canada; Università degli Studi di Verona; Ministero dell’Istruzione, dell’Università e della Ricerca; Consorzio Interuniversitario Nazionale per la Scienza e Tecnologia dei Materiali; University of Calgary","keywords":"Photoluminescence; Nanomaterials; Nanotechnology; Nanoparticle; Materials science; Quantum dot; Nanochemistry; Selenium; Fluorescence; Optoelectronics; Optics; Physics","score_opus":0.03966313442423592,"score_gpt":0.2523108402951563,"score_spread":0.2126477058709204,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3041849462","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9942734,0.0014614596,0.0000020108503,0.00012634418,0.0022294843,0.0005902677,0.000016849986,0.00022723424,0.0010729142],"genre_scores_gemma":[0.9980234,0.000044320124,0.0013366241,0.00010441808,0.0001738891,0.0001214052,0.0000023518687,0.000053293483,0.00014029835],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99730843,0.00016163547,0.000694061,0.00061512523,0.00046224208,0.00075849076],"domain_scores_gemma":[0.9981506,0.00022096132,0.0003108515,0.0007652656,0.00039704668,0.00015526218],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00048961194,0.00033444844,0.00055790757,0.00008094164,0.000240536,0.00004564384,0.00066208077,0.00032928307,0.00026500976],"category_scores_gemma":[0.0008392293,0.0002685026,0.00021273916,0.00078287744,0.0006642562,0.00015211337,0.00013838278,0.00016344765,0.00043147965],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0016281012,0.00016180305,0.0010787606,0.00012885693,0.00005759875,8.6534845e-7,0.00035171746,0.0000011604244,0.99582225,0.00002598424,0.0003998965,0.00034299202],"study_design_scores_gemma":[0.0007816718,0.00059829705,0.000246693,0.00015112758,0.00009707431,0.000016636006,0.00025510747,0.0014342555,0.99123377,0.000016081402,0.0048133475,0.00035595178],"about_ca_topic_score_codex":0.0003562222,"about_ca_topic_score_gemma":0.000062122584,"teacher_disagreement_score":0.004588507,"about_ca_system_score_codex":0.00021922763,"about_ca_system_score_gemma":0.00007498404,"threshold_uncertainty_score":0.9999767},"labels":[],"label_agreement":null},{"id":"W3047663541","doi":"10.1515/nanoph-2020-0321","title":"Demonstration of biaxially tensile‐strained Ge/SiGe multiple quantum well (MQW) electroabsorption modulators with low polarization dependence","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":7,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Wuhan National Laboratory for Optoelectronics; National Natural Science Foundation of China; College of Family Physicians of Canada","keywords":"Polarizer; Materials science; Polarization (electrochemistry); Optoelectronics; Waveguide; Ultimate tensile strength; Tensile strain; Optics; Quantum dot; Birefringence; Composite material; Physics","score_opus":0.005335524729652811,"score_gpt":0.19184446074187858,"score_spread":0.18650893601222576,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3047663541","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9708743,0.00013214331,0.02578918,0.00001320171,0.00022401707,0.00033884926,0.000015907119,0.00021947197,0.002392905],"genre_scores_gemma":[0.9943378,0.0000870794,0.005350998,0.00003803223,0.000041878637,0.00001316032,0.00004004101,0.00004468113,0.00004633326],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9986525,0.000024606506,0.00036034954,0.00026944673,0.0003351784,0.00035789903],"domain_scores_gemma":[0.9992238,0.00005783663,0.0001046191,0.00028979982,0.00022258243,0.000101321995],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00016197834,0.0002241131,0.00024921875,0.000090944915,0.00007730884,0.00003430278,0.00017436754,0.00021805245,0.000045429446],"category_scores_gemma":[0.000041836985,0.00020340605,0.000056522353,0.0004173383,0.00013740564,0.00028327262,0.000016878384,0.00019002771,0.000044918797],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00010613676,0.00006537817,0.0029724475,0.00010110972,0.000055035114,0.0000045931833,0.0001650987,0.006052557,0.9867365,0.0032295918,0.000024331574,0.00048724044],"study_design_scores_gemma":[0.00044126422,0.00026284024,0.004726037,0.000057201218,0.000028893646,0.000010172011,0.000033013595,0.6365408,0.3574142,0.00014448729,0.00013602867,0.00020511818],"about_ca_topic_score_codex":0.00006760961,"about_ca_topic_score_gemma":0.0002743301,"teacher_disagreement_score":0.6304882,"about_ca_system_score_codex":0.000087745626,"about_ca_system_score_gemma":0.00011191915,"threshold_uncertainty_score":0.8294658},"labels":[],"label_agreement":null},{"id":"W3048657665","doi":"10.1515/nanoph-2020-0172","title":"Primer on silicon neuromorphic photonic processors: architecture and compiler","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Neural Networks and Reservoir Computing","field":"Computer Science","cited_by":51,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Queen's University","funders":"Natural Sciences and Engineering Research Council of Canada; National Science Foundation","keywords":"Neuromorphic engineering; Photonics; Computer science; Computer architecture; Signal processing; Reconfigurability; Silicon photonics; Microelectronics; Digital signal processing; Artificial neural network; Electronic engineering; Artificial intelligence; Engineering; Telecommunications; Computer hardware; Electrical engineering; Materials science","score_opus":0.019319883552134178,"score_gpt":0.23710562677293898,"score_spread":0.2177857432208048,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3048657665","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9923295,0.00039305838,0.002925993,0.0011341939,0.00072594045,0.00036412457,0.0000017209949,0.00024993613,0.0018755569],"genre_scores_gemma":[0.9892108,0.000057543533,0.007895259,0.0024172603,0.00015919814,0.0000116359715,0.0000014154851,0.000024644818,0.00022224223],"study_design_codex":"design_other","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9981995,0.00007447037,0.00023299943,0.000677188,0.00033079353,0.0004850249],"domain_scores_gemma":[0.99883103,0.00013599836,0.00011730468,0.0006515234,0.00010580141,0.00015832385],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.0001986617,0.0002465575,0.00023610855,0.00007755938,0.0003224856,0.00020499983,0.00080898876,0.00011528296,0.000017195418],"category_scores_gemma":[0.000030997,0.00019132177,0.00006086936,0.00047916613,0.00016597228,0.00013599184,0.0004483586,0.00040380107,0.00005616062],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00093775964,0.0024718887,0.0075559127,0.00096697774,0.0004676952,0.0010764073,0.012143951,0.021642713,0.40129972,0.068868935,0.021405565,0.46116248],"study_design_scores_gemma":[0.0012382249,0.0019289248,0.0026230968,0.00023503341,0.000015936008,0.0002629657,0.000011121393,0.8315954,0.07328588,0.003620775,0.084375575,0.00080703205],"about_ca_topic_score_codex":0.000012376484,"about_ca_topic_score_gemma":0.000011419122,"teacher_disagreement_score":0.80995274,"about_ca_system_score_codex":0.000022648326,"about_ca_system_score_gemma":0.00007922705,"threshold_uncertainty_score":0.78018755},"labels":[],"label_agreement":null},{"id":"W3092453921","doi":"10.1515/nanoph-2020-0571","title":"Interface‐induced field‐like optical spin torque in a ferromagnet/heavy metal heterostructure","year":2020,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Magnetic properties of thin films","field":"Physics and Astronomy","cited_by":12,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Innovation Cluster (Canada)","funders":"Center for Spintronics Research Network, Tohoku University; Japan Society for the Promotion of Science","keywords":"Spintronics; Condensed matter physics; Ferromagnetism; Magnetization; Nanomagnet; Materials science; Physics; Magnetic field","score_opus":0.01522466368875139,"score_gpt":0.24837426801560084,"score_spread":0.23314960432684945,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3092453921","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9884253,0.00021687931,0.00017268845,0.0020275794,0.0005598815,0.00039219926,0.000018549017,0.000056814595,0.008130104],"genre_scores_gemma":[0.99368817,0.0000019889333,0.0042836834,0.0014223908,0.00010722336,0.0000383739,0.00001151336,0.00003421633,0.00041245867],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9984282,0.000049795257,0.00038727035,0.0004629207,0.00023871838,0.0004330646],"domain_scores_gemma":[0.9992575,0.000040025694,0.000076587625,0.00037427622,0.0000391849,0.00021243084],"candidate_categories":["metaepi_narrow","insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.0000886653,0.0002816332,0.0003824839,0.000032661268,0.000052416457,0.000081938924,0.00049096456,0.00014476597,0.002526098],"category_scores_gemma":[0.00004531756,0.00025484196,0.00014809643,0.00018738126,0.00004318763,0.00012788225,0.00029813565,0.00058972294,0.00013796041],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0007502441,0.00043461655,0.004912546,0.0001660005,0.00019671893,0.000086816064,0.0038662972,0.0005309173,0.9461728,0.004428414,0.010221779,0.028232846],"study_design_scores_gemma":[0.0032756773,0.002299697,0.0012250288,0.00009700496,0.00008262876,0.0000104818555,0.00070765696,0.0373482,0.9067939,0.0012002378,0.04575514,0.0012043493],"about_ca_topic_score_codex":0.0002975794,"about_ca_topic_score_gemma":0.000022654975,"teacher_disagreement_score":0.039378908,"about_ca_system_score_codex":0.00003655751,"about_ca_system_score_gemma":0.000100193705,"threshold_uncertainty_score":0.9999904},"labels":[],"label_agreement":null},{"id":"W3094065577","doi":"10.1515/nanoph-2020-0309","title":"Scaling capacity of fiber‐optic transmission systems via silicon photonics","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":137,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Université Laval","funders":"Natural Sciences and Engineering Research Council of Canada","keywords":"Silicon photonics; Photonics; Computer science; Multiplexing; Photonic integrated circuit; Optical engineering; Transmission (telecommunications); Electronic engineering; Telecommunications; Optoelectronics; Materials science; Physics; Engineering; Optics","score_opus":0.011947879710245182,"score_gpt":0.21441691853785066,"score_spread":0.20246903882760547,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3094065577","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9759675,0.0020029529,0.0017587718,0.000006299214,0.0008016236,0.00034175828,0.00002333359,0.00030023715,0.018797478],"genre_scores_gemma":[0.99091154,0.00028484137,0.008515931,0.000024727193,0.00004169987,0.000021554935,0.0000067628166,0.000060698956,0.0001322548],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99831605,0.000032381096,0.0005398028,0.000287248,0.0003473634,0.0004771361],"domain_scores_gemma":[0.9990051,0.00012455918,0.00007808376,0.00044692436,0.00014584123,0.00019948847],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.000285126,0.00027741873,0.0004532731,0.00007474342,0.00009651163,0.000035114033,0.00031247668,0.00029622484,0.0002495573],"category_scores_gemma":[0.000022174412,0.00025750778,0.00014045507,0.0003390735,0.00018228352,0.00014335576,0.00003156247,0.00027259282,0.00018039811],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000113158014,0.00022913954,0.000070864735,0.0022359057,0.0002852711,0.000025312132,0.0020431683,0.029387191,0.9510242,0.0035557363,0.00025335827,0.010776746],"study_design_scores_gemma":[0.00033870235,0.00010968846,0.000054889868,0.00017165343,0.000046123623,0.000020588486,0.00003676555,0.77676344,0.19741662,0.00010675508,0.024668125,0.00026664333],"about_ca_topic_score_codex":0.000094392926,"about_ca_topic_score_gemma":0.000008596399,"teacher_disagreement_score":0.7536075,"about_ca_system_score_codex":0.00012089156,"about_ca_system_score_gemma":0.000052013667,"threshold_uncertainty_score":0.9999877},"labels":[],"label_agreement":null},{"id":"W3096219189","doi":"10.1515/nanoph-2020-0490","title":"Dynamically controlling local field enhancement at an epsilon‐near‐zero/dielectric interface via nonlinearities of an epsilon‐near‐zero medium","year":2018,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":19,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Ottawa","funders":"Advanced Research Projects Agency; Defense Advanced Research Projects Agency; Canada Research Chairs; U.S. Department of Defense","keywords":"Dielectric; Electric field; Local field; Physics; Nonlinear system; Electromagnetic field; Photonics; Optics; Field (mathematics); Condensed matter physics; Nonlinear optics; Zero (linguistics); Materials science; Optoelectronics; Quantum mechanics","score_opus":0.009232785102095067,"score_gpt":0.25596389174660555,"score_spread":0.24673110664451048,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3096219189","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9231605,0.0008676785,0.072656736,0.00011566447,0.00074905605,0.00048505954,0.000060030598,0.00023596013,0.0016693055],"genre_scores_gemma":[0.8431701,0.0002710412,0.15574646,0.00013180664,0.0000052030055,0.00004014401,0.00005226736,0.00008826213,0.00049469847],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9965582,0.00010066086,0.0008109177,0.0005992572,0.0008364892,0.0010944876],"domain_scores_gemma":[0.99796045,0.0003571089,0.00012241091,0.00078810396,0.00035824403,0.00041368857],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0006723448,0.0004771619,0.0007423909,0.00013370166,0.0003125103,0.00013096516,0.0007631133,0.00049087655,0.0004895473],"category_scores_gemma":[0.00012279667,0.00047818132,0.00015585031,0.0004288458,0.00046624796,0.00031543002,0.00019908494,0.00073974696,0.00017078166],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0028357438,0.0011686402,0.00076964323,0.0007462249,0.00077148183,0.0001464592,0.0033171282,0.33562696,0.6435574,0.00022300366,0.0022796153,0.008557663],"study_design_scores_gemma":[0.0008021417,0.0017038501,0.00004299981,0.00006395253,0.00003246143,0.000016203123,0.0000652448,0.7647132,0.22950116,0.0001525484,0.0025337585,0.0003724201],"about_ca_topic_score_codex":0.00022261529,"about_ca_topic_score_gemma":0.0007471603,"teacher_disagreement_score":0.4290863,"about_ca_system_score_codex":0.00043455168,"about_ca_system_score_gemma":0.00027059313,"threshold_uncertainty_score":0.999767},"labels":[],"label_agreement":null},{"id":"W3109184920","doi":"10.1515/nanoph-2020-0474","title":"Nanostructured inorganic electrochromic materials for light applications","year":2020,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Transition Metal Oxide Nanomaterials","field":"Materials Science","cited_by":190,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Alberta","funders":"Natural Sciences and Engineering Research Council of Canada; Alberta Innovates","keywords":"Electrochromism; Electrochromic devices; Materials science; Prussian blue; Nanotechnology; Nanomaterials; Doping; Optoelectronics; Electrode; Electrochemistry; Chemistry","score_opus":0.010268226900605089,"score_gpt":0.2273424840079954,"score_spread":0.2170742571073903,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3109184920","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9902107,0.00025183518,0.0044138078,0.0011947012,0.0007986205,0.0019120607,0.0006637887,0.00042632534,0.00012814236],"genre_scores_gemma":[0.9758539,0.00003132393,0.021166643,0.0018188481,0.00026202682,0.0006229683,0.000092898146,0.00007693322,0.00007442731],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9979467,0.000078199446,0.00058983575,0.00058827177,0.0003259476,0.0004710775],"domain_scores_gemma":[0.99893105,0.000051905175,0.00023167483,0.0003795614,0.00021054989,0.00019528728],"candidate_categories":["metaepi_narrow","insufficient_payload"],"consensus_categories":["insufficient_payload"],"category_scores_codex":[0.00033247934,0.00026955982,0.00047778588,0.000040150462,0.00019710405,0.00018131646,0.00050834264,0.00019660378,0.0021769009],"category_scores_gemma":[0.00011568023,0.0002558019,0.000104816216,0.00028833668,0.00005171237,0.00019634969,0.000058980488,0.00006355966,0.000832168],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00013952465,0.00002141997,0.000001410219,0.00010742498,0.000010891235,0.0000014350231,0.00015921747,0.0000045664565,0.99653584,0.0018153354,0.0011562373,0.000046676752],"study_design_scores_gemma":[0.0007550356,0.00014835609,0.00003162202,0.000007942631,0.000049691884,0.000012519972,0.000015764153,0.000019341172,0.9367651,0.0008265474,0.061094213,0.00027391085],"about_ca_topic_score_codex":0.000005233014,"about_ca_topic_score_gemma":0.0000035540031,"teacher_disagreement_score":0.059937976,"about_ca_system_score_codex":0.000108648055,"about_ca_system_score_gemma":0.00022969395,"threshold_uncertainty_score":0.99998945},"labels":[],"label_agreement":null},{"id":"W3114234493","doi":"10.1515/nanoph-2020-0455","title":"High‐efficiency and high‐speed germanium photodetector enabled by multiresonant photonic crystal","year":2020,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":48,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"National Key Research and Development Program of China; Wuhan National Laboratory for Optoelectronics; National Natural Science Foundation of China; College of Family Physicians of Canada","keywords":"Photodetector; Optoelectronics; Materials science; Germanium; Photonics; Optics; Bandwidth (computing); Photonic integrated circuit; Quantum efficiency; Photonic crystal; Broadband; Electronic circuit; Silicon; Computer science; Telecommunications; Physics","score_opus":0.0066373009806001805,"score_gpt":0.18880026883560513,"score_spread":0.18216296785500496,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3114234493","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99120134,0.004024772,0.00040245912,0.0001792472,0.0005315354,0.00058371166,0.0002195961,0.0007655241,0.0020917987],"genre_scores_gemma":[0.99651474,0.0011152703,0.0012501491,0.0007485615,0.000053505624,0.000038313734,0.0000388115,0.00010741976,0.00013325593],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99765456,0.000033989174,0.00049425033,0.0006050394,0.00042038842,0.00079180376],"domain_scores_gemma":[0.99887025,0.000121180434,0.00007177229,0.00035363072,0.000059503196,0.0005236739],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00014161473,0.00047381833,0.0005774178,0.00005231612,0.00015001213,0.00012142593,0.00039992543,0.00028422225,0.00042104954],"category_scores_gemma":[0.00004249504,0.0004448229,0.000116049225,0.0004070281,0.00012842786,0.00020424469,0.00013948994,0.00048733054,0.00015454907],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00008453732,0.00007756302,0.000024542001,0.00026817387,0.00008278932,0.000061573635,0.0005289296,0.0018070949,0.99417835,0.0005890237,0.0016973622,0.000600064],"study_design_scores_gemma":[0.001524482,0.00019298692,0.00010068078,0.000031184863,0.000050955427,0.000012343939,0.000068195965,0.52255034,0.43242174,0.000031871154,0.04242105,0.00059418636],"about_ca_topic_score_codex":0.00013486175,"about_ca_topic_score_gemma":0.000015642185,"teacher_disagreement_score":0.5617566,"about_ca_system_score_codex":0.00012427194,"about_ca_system_score_gemma":0.00007134814,"threshold_uncertainty_score":0.9998003},"labels":[],"label_agreement":null},{"id":"W3138614672","doi":"10.1515/nanoph-2021-0007","title":"Asymmetric Ge/SiGe coupled quantum well modulators","year":2021,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":10,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Wuhan National Laboratory for Optoelectronics; National Natural Science Foundation of China; College of Family Physicians of Canada","keywords":"Extinction ratio; Optoelectronics; Biasing; Materials science; Modulation (music); Photonics; Silicon photonics; Electro-absorption modulator; Bandwidth (computing); Voltage; Optical modulator; Waveguide; Quantum well; Physics; Optics; Phase modulation; Quantum dot laser; Semiconductor; Computer science; Telecommunications; Semiconductor laser theory","score_opus":0.008127625115542634,"score_gpt":0.20882669856921582,"score_spread":0.2006990734536732,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3138614672","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.913734,0.009920926,0.0010751435,0.00005451602,0.0016989243,0.00018316811,0.000018847222,0.000573635,0.072740845],"genre_scores_gemma":[0.9948549,0.0017997539,0.0023912434,0.00023556965,0.00003825486,0.000018306497,0.000023182378,0.00006426732,0.00057450624],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9985929,0.000018847546,0.0003063208,0.00029635848,0.0003057308,0.0004798415],"domain_scores_gemma":[0.9991219,0.00011454936,0.000029799743,0.00045461353,0.000086501954,0.0001926112],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00013392756,0.00023110033,0.00031871593,0.00008466278,0.00007145439,0.00006486616,0.00021994617,0.00020708301,0.00043590306],"category_scores_gemma":[0.00006848912,0.00023408973,0.00013749514,0.00092647725,0.000034117307,0.00011617199,0.00006411317,0.00030077915,0.0006838919],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00016470758,0.0017779417,0.005001554,0.0030556784,0.0022224542,0.003807746,0.001479738,0.22761779,0.50494313,0.20137875,0.026009131,0.022541385],"study_design_scores_gemma":[0.00039148654,0.000024255964,0.0007613295,0.000023236633,0.000032012693,0.000019986723,0.000038070542,0.83535093,0.0492301,0.0005191268,0.11329659,0.00031285518],"about_ca_topic_score_codex":0.000017919503,"about_ca_topic_score_gemma":0.00001964396,"teacher_disagreement_score":0.6077332,"about_ca_system_score_codex":0.00012973348,"about_ca_system_score_gemma":0.000096115,"threshold_uncertainty_score":0.95459026},"labels":[],"label_agreement":null},{"id":"W3175231874","doi":"10.1515/nanoph-2021-0220","title":"Porphyrin‐lipid nanovesicles (Porphysomes) are effective photosensitizers for photodynamic therapy","year":2021,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Nanoplatforms for cancer theranostics","field":"Engineering","cited_by":41,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Princess Margaret Cancer Centre; University of Toronto","funders":"Canadian Institutes of Health Research; Terry Fox Research Institute; University of Toronto","keywords":"Photodynamic therapy; Photosensitizer; Photothermal therapy; In vivo; Liposome; Drug delivery; Hematoporphyrin; Cancer research; Medicine; Pharmacology; Chemistry; Materials science; Nanotechnology; Photochemistry; Biology","score_opus":0.006990384402191322,"score_gpt":0.2125841090519114,"score_spread":0.2055937246497201,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3175231874","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9892819,0.0036452697,0.0011598449,0.000041189887,0.0023264796,0.0014781513,0.00035867083,0.0006634743,0.0010450362],"genre_scores_gemma":[0.9915063,0.0020444822,0.0045403475,0.00048966595,0.0001665487,0.0005033735,0.00012565519,0.0002810443,0.0003425775],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99795026,0.000026728812,0.00042419188,0.000522181,0.0003393838,0.00073727657],"domain_scores_gemma":[0.99847424,0.0002986462,0.0001241744,0.0006718754,0.00026021383,0.00017084586],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0001764696,0.00050254114,0.0006096966,0.00010310717,0.00016535899,0.00009320381,0.00026682325,0.00029128848,0.00008724016],"category_scores_gemma":[0.00006295604,0.0005190958,0.00037957195,0.00053911796,0.000078269455,0.00020693727,0.000044988938,0.00029668421,0.00005832584],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00013916889,0.000077053344,0.00006358883,0.0001631418,0.0002788645,0.000066171146,0.00022315356,0.0025176364,0.98781794,0.00012084323,0.00076043606,0.0077719716],"study_design_scores_gemma":[0.002794929,0.00013016784,0.0003212454,0.00009416302,0.000046180612,0.000046021494,0.00018136235,0.014693469,0.93332785,0.00088730967,0.046840303,0.0006369932],"about_ca_topic_score_codex":0.000011494752,"about_ca_topic_score_gemma":0.000055789136,"teacher_disagreement_score":0.05449011,"about_ca_system_score_codex":0.0004213808,"about_ca_system_score_gemma":0.00015253032,"threshold_uncertainty_score":0.99972606},"labels":[],"label_agreement":null},{"id":"W3191234098","doi":"10.1515/nanoph-2021-0241","title":"Repeated porphyrin lipoprotein‐based photodynamic therapy controls distant disease in mouse mesothelioma via the abscopal effect","year":2021,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Nanoplatforms for cancer theranostics","field":"Engineering","cited_by":20,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Toronto General Hospital; Princess Margaret Cancer Centre; McMaster University; University of Toronto; University Health Network","funders":"Natural Sciences and Engineering Research Council of Canada; Princess Margaret Cancer Foundation","keywords":"Photodynamic therapy; Immune system; Cancer research; Abscopal effect; Photosensitizer; Mesothelioma; Lymph node; Immunology; Medicine; Flow cytometry; CD8; Cytokine; Immunotherapy; Chemistry; Pathology","score_opus":0.004708528974529546,"score_gpt":0.2063031019002423,"score_spread":0.20159457292571276,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3191234098","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9902968,0.005797931,0.0010219853,0.000074449104,0.0005812192,0.0014252592,0.0001697009,0.00039550097,0.00023715322],"genre_scores_gemma":[0.99801135,0.00053599133,0.0002961861,0.00026971503,0.00003741256,0.00041680882,0.00009386126,0.00016536673,0.00017332974],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99783,0.000102773476,0.0005286381,0.00043536557,0.00046499076,0.0006382368],"domain_scores_gemma":[0.99828464,0.00025964808,0.000089130575,0.0010959613,0.00008010616,0.0001904988],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0003753153,0.00046415106,0.0005008647,0.00010973199,0.000111415626,0.00010872462,0.0004114189,0.00017482368,0.00015877253],"category_scores_gemma":[0.00008738779,0.00035037484,0.00025359562,0.0006040151,0.000085655985,0.00012104335,0.00004101887,0.00045660627,0.000047376718],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00068236224,0.00009855564,0.0004366934,0.00010600515,0.000104486084,0.00044269382,0.00012057039,0.023235155,0.9717725,0.000032689764,0.000029757073,0.0029385458],"study_design_scores_gemma":[0.004393747,0.000136728,0.0006141813,0.00009644326,0.00003551343,0.000008320559,0.0000103662305,0.22780743,0.76241636,0.0002680884,0.0037541657,0.000458642],"about_ca_topic_score_codex":0.0001666747,"about_ca_topic_score_gemma":0.00043006396,"teacher_disagreement_score":0.20935611,"about_ca_system_score_codex":0.00043545265,"about_ca_system_score_gemma":0.00022592049,"threshold_uncertainty_score":0.9998948},"labels":[],"label_agreement":null},{"id":"W3194938146","doi":"10.1515/nanoph-2021-0207","title":"Smart NIR‐light and pH responsive doxorubicin‐loaded GNRs@SBA‐15‐SH nanocomposite for chemo‐photothermal therapy of cancer","year":2021,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Nanoplatforms for cancer theranostics","field":"Engineering","cited_by":29,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Manitoba","funders":"Shahid Chamran University of Ahvaz","keywords":"Photothermal therapy; Doxorubicin; Nanocomposite; Biocompatibility; Nanorod; Materials science; Nanotechnology; Mesoporous silica; Cancer cell; Photothermal effect; Chemistry; Chemotherapy; Cancer; Mesoporous material; Medicine; Organic chemistry; Surgery","score_opus":0.00988069951184998,"score_gpt":0.23867892010093494,"score_spread":0.22879822058908497,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3194938146","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.968525,0.028025037,0.0002967244,0.0001436449,0.0010097544,0.0008919203,0.00027750293,0.00017120782,0.0006592228],"genre_scores_gemma":[0.981715,0.011254845,0.0048016375,0.0006052369,0.00011637866,0.00037193057,0.000046486413,0.00024264731,0.0008457949],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9982165,0.000024491288,0.0005378414,0.00036589793,0.0002992956,0.0005559733],"domain_scores_gemma":[0.9986605,0.00020412658,0.00014032339,0.00052663276,0.00032439333,0.00014403334],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00018109946,0.0004063991,0.00063875323,0.00010509124,0.00011576672,0.000051376064,0.00024505565,0.00029676215,0.00017088097],"category_scores_gemma":[0.000039236438,0.0003949137,0.00018947369,0.00044786272,0.00007012139,0.00016595906,0.00005727396,0.00024020017,0.000006225783],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00047761406,0.000051808838,0.00028011078,0.00020035428,0.00030507369,0.00001567593,0.00096232444,0.0005616955,0.9917714,0.00008355288,0.0007036971,0.004586663],"study_design_scores_gemma":[0.0028248704,0.00013506034,0.00031098575,0.00015401555,0.00005637959,0.000018239696,0.00010143235,0.0026065216,0.89097995,0.00019568823,0.1022065,0.00041037067],"about_ca_topic_score_codex":0.00006043205,"about_ca_topic_score_gemma":0.00012367888,"teacher_disagreement_score":0.101502806,"about_ca_system_score_codex":0.00020299225,"about_ca_system_score_gemma":0.00026484116,"threshold_uncertainty_score":0.9998503},"labels":[],"label_agreement":null},{"id":"W3195000182","doi":"10.1515/nanoph-2021-0225","title":"A high‐performance TE modulator/TM‐pass polarizer using selective mode shaping in a VO <sub>2</sub> ‐based side‐polished fiber","year":2021,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Advanced Fiber Optic Sensors","field":"Engineering","cited_by":43,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Victoria","funders":"Tarbiat Modares University","keywords":"Extinction ratio; Polarizer; Insertion loss; Materials science; Optoelectronics; Optical modulator; Optics; Optical power; Polarization (electrochemistry); Phase modulation; Birefringence; Laser; Chemistry; Physics","score_opus":0.012992487007869329,"score_gpt":0.22619648941537657,"score_spread":0.21320400240750723,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3195000182","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99505264,0.00046282794,0.0029145686,0.000026162641,0.0004415426,0.00034647746,0.000034270575,0.00040016082,0.0003213447],"genre_scores_gemma":[0.95525527,0.000055022694,0.044167213,0.00019071059,0.00005279132,0.000039654995,0.000024066694,0.00018105906,0.00003419027],"study_design_codex":"simulation_or_modeling","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9975151,0.00005221364,0.0005492721,0.0005988338,0.00039767567,0.00088691094],"domain_scores_gemma":[0.9988225,0.00012743338,0.00009448106,0.00060057617,0.00019859103,0.00015640669],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00011919846,0.0004608774,0.0005626758,0.00022412771,0.00011762453,0.00007143058,0.0002094347,0.0003637156,0.00002787126],"category_scores_gemma":[0.00009511813,0.00055976375,0.00012131535,0.001248915,0.000053713324,0.00044165755,0.00007977198,0.0007222788,0.00004876744],"study_design_candidate":"simulation_or_modeling","study_design_consensus":"simulation_or_modeling","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000019148747,0.000026112242,0.00012791289,0.0000686583,0.00003428833,0.0000774308,0.00021388552,0.5351993,0.46359095,0.000016310367,0.000009997199,0.00061599485],"study_design_scores_gemma":[0.0006679801,0.000013262534,0.0003475738,0.00012380746,0.000018700579,0.00003102774,0.000032470598,0.51415044,0.48411888,0.000078226214,0.000079614474,0.00033801727],"about_ca_topic_score_codex":0.00009334273,"about_ca_topic_score_gemma":0.00013094506,"teacher_disagreement_score":0.041252643,"about_ca_system_score_codex":0.0010828408,"about_ca_system_score_gemma":0.00029995883,"threshold_uncertainty_score":0.9996854},"labels":[],"label_agreement":null},{"id":"W3196103355","doi":"10.1515/nanoph-2021-0110","title":"A review of silicon subwavelength gratings: building break‐through devices with anisotropic metamaterials","year":2021,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":145,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"National Research Council Canada","funders":"Ministerio de Educación, Cultura y Deporte; Universidad de Málaga","keywords":"Metamaterial; Photonics; Nanophotonics; Silicon photonics; Materials science; Grating; Silicon; Photonic metamaterial; Optoelectronics; Computer science; Nanotechnology; Optics; Physics","score_opus":0.024629445703078155,"score_gpt":0.29361152302056553,"score_spread":0.26898207731748736,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3196103355","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.00020003067,0.9959114,0.000045012785,0.000005505571,0.0004240558,0.0010622353,0.00016191292,0.00021027753,0.0019795795],"genre_scores_gemma":[0.000027517257,0.9885711,0.01056386,0.00018460113,0.000053616328,0.00023228156,0.00015626445,0.00018364267,0.000027098917],"study_design_codex":"systematic_review","study_design_gemma":"not_applicable","domain_scores_codex":[0.99665725,0.00017647716,0.0015199335,0.00062365516,0.0004336083,0.00058908714],"domain_scores_gemma":[0.99791145,0.0003148713,0.0005708778,0.00087128166,0.00019940078,0.00013211934],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0003824271,0.000875599,0.004539714,0.000079843994,0.00006730275,0.00008536115,0.0006184661,0.00046579217,0.00029109558],"category_scores_gemma":[0.000113515394,0.000648178,0.0006448776,0.00088297867,0.00009737343,0.00022310049,0.0001332104,0.00047894454,0.000029415578],"study_design_candidate":"systematic_review","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0000033377466,0.000067565175,6.842408e-7,0.8725997,0.0012287002,0.00007531309,0.00007262285,0.000019041014,0.00022032567,0.0022068967,0.0004002159,0.123105556],"study_design_scores_gemma":[0.0001267114,0.000059799186,1.9982046e-7,0.23949273,0.0017428749,0.00009786868,0.000011806801,0.00013670196,0.00089198846,0.000010821085,0.756888,0.000540511],"about_ca_topic_score_codex":0.000033189808,"about_ca_topic_score_gemma":0.000020961957,"teacher_disagreement_score":0.7564878,"about_ca_system_score_codex":0.00018500703,"about_ca_system_score_gemma":0.00044667503,"threshold_uncertainty_score":0.99959695},"labels":[],"label_agreement":null},{"id":"W3212143346","doi":"10.1515/nanoph-2021-0510","title":"Scalable and effective multi‐level entangled photon states: a promising tool to boost quantum technologies","year":2021,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Quantum Information and Cryptography","field":"Computer Science","cited_by":97,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut National de la Recherche Scientifique","funders":"Natural Sciences and Engineering Research Council of Canada; Australian Research Council; European Commission; 1000 Talents Sichuan Program; John Templeton Foundation","keywords":"Computer science; Quantum entanglement; Quantum sensor; Photon entanglement; Quantum technology; Photon; Scalability; Quantum computer; Quantum metrology; Computer engineering; Quantum key distribution; Robustness (evolution); Electronic engineering; Photonics; Physics; Quantum network; Quantum; Quantum mechanics; Engineering; Open quantum system","score_opus":0.014118495594599842,"score_gpt":0.24611068106378786,"score_spread":0.231992185469188,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3212143346","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.8789065,0.00052224833,0.11780571,0.0005726275,0.00031364046,0.0008606164,0.000026573258,0.00064866815,0.00034340436],"genre_scores_gemma":[0.75770235,0.0003235982,0.24018528,0.0013559634,0.000005722496,0.0002575463,0.0000140370485,0.00002274307,0.00013275538],"study_design_codex":"design_other","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99851483,0.000045559187,0.00030373322,0.00044713108,0.00028864524,0.00040009484],"domain_scores_gemma":[0.99891394,0.00009917939,0.00009764835,0.0005709331,0.00022813694,0.000090140085],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00028385164,0.00020904401,0.0002512307,0.00017379252,0.00022885352,0.00039815984,0.00042918182,0.00013021384,0.000011498431],"category_scores_gemma":[0.00018433425,0.00019461979,0.00007489801,0.0011235732,0.00006436936,0.00055904133,0.00045109252,0.00019856954,0.000059539474],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0002577635,0.0013308856,0.004108297,0.0008038846,0.0003682537,0.00042070993,0.026994541,0.00044879486,0.37935036,0.18001838,0.0045245793,0.40137354],"study_design_scores_gemma":[0.0019789122,0.0003414639,0.0021471418,0.00019410525,0.000016792334,0.00010053707,0.0019509037,0.35340926,0.59649456,0.005509748,0.03713901,0.000717543],"about_ca_topic_score_codex":0.000016310218,"about_ca_topic_score_gemma":0.000017269134,"teacher_disagreement_score":0.40065598,"about_ca_system_score_codex":0.00007840442,"about_ca_system_score_gemma":0.00013200703,"threshold_uncertainty_score":0.79363644},"labels":[],"label_agreement":null},{"id":"W3212891718","doi":"10.1515/nanoph-2021-0501","title":"Reconfigurable terahertz metasurfaces coherently controlled by wavelength‐scale‐structured light","year":2021,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":19,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Ottawa","funders":"Army Research Office; Natural Sciences and Engineering Research Council of Canada; Defense Advanced Research Projects Agency; Canada Research Chairs","keywords":"Terahertz radiation; Metamaterial; Optoelectronics; Optics; Physics; Polarization (electrochemistry); Wavelength","score_opus":0.009636215167248703,"score_gpt":0.2326288332591412,"score_spread":0.2229926180918925,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W3212891718","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.98438376,0.00493154,0.000059758553,0.0008453415,0.001670705,0.0007983752,0.00039884416,0.0001618252,0.006749865],"genre_scores_gemma":[0.93647945,0.0015878701,0.041241717,0.0010957981,0.00007499123,0.00059601606,0.00028120042,0.0001161892,0.018526746],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9969513,0.0003302756,0.00083829847,0.0007825638,0.00049340894,0.00060415827],"domain_scores_gemma":[0.99796104,0.00015031929,0.00039454576,0.0009213431,0.00033991373,0.00023284995],"candidate_categories":["metaepi_narrow","insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.00086379226,0.00037405884,0.001031018,0.00003142165,0.000349731,0.0003915535,0.0004798139,0.00022772001,0.010586129],"category_scores_gemma":[0.00015963778,0.0003028628,0.00022246334,0.0003005639,0.00007324474,0.0002046344,0.0000680284,0.00016316288,0.0007284221],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0001123092,0.00010845141,0.000013813237,0.000029570248,0.000059755574,0.0000064754277,0.00012274992,0.000019937397,0.9892213,0.00024463623,0.009402768,0.00065823767],"study_design_scores_gemma":[0.0017172764,0.000027639491,0.00001862248,0.000013434705,0.000105383006,0.000015344502,0.000064505344,0.00029566878,0.66541994,0.00031813123,0.3317596,0.0002444506],"about_ca_topic_score_codex":0.00006313772,"about_ca_topic_score_gemma":0.00007941875,"teacher_disagreement_score":0.32380137,"about_ca_system_score_codex":0.00006941189,"about_ca_system_score_gemma":0.00023865885,"threshold_uncertainty_score":0.99994236},"labels":[],"label_agreement":null},{"id":"W4200560005","doi":"10.1515/nanoph-2021-0449","title":"The effects of bending on plasmonic modes in nanowires and planar structures","year":2021,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":3,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Canadian Light Source (Canada); McMaster University Medical Centre; McMaster University","funders":"Natural Sciences and Engineering Research Council of Canada","keywords":"Plasmon; Nanowire; Bending; Planar; Materials science; Nanostructure; Optoelectronics; Surface plasmon; Enhanced Data Rates for GSM Evolution; Optics; Nanotechnology; Physics; Telecommunications","score_opus":0.006691812461227526,"score_gpt":0.22119345608946206,"score_spread":0.21450164362823454,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4200560005","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99207556,0.00613786,0.000007462468,0.000034594435,0.0002160427,0.00012756385,0.0000116118845,0.000035698777,0.001353613],"genre_scores_gemma":[0.9935453,0.0053539276,0.000921044,0.000012332496,0.000001662951,0.000013691916,0.0000033056087,0.000021083793,0.00012766846],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99903923,0.00004329005,0.00018521966,0.00016670501,0.00024292136,0.0003226323],"domain_scores_gemma":[0.9986163,0.0010661901,0.000020503754,0.00021861157,0.000022821803,0.000055623525],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00014270717,0.00013703297,0.00020233117,0.000056754423,0.00008645991,0.000038588707,0.00014610295,0.00010998422,0.0000050299195],"category_scores_gemma":[0.00018469285,0.000105378815,0.000037172114,0.00020417494,0.00007944303,0.000043435695,0.000038895807,0.00028692491,0.00000287126],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00020044744,0.00009680719,0.008456732,0.0014541848,0.00028835563,0.0005613603,0.0013576908,0.14000848,0.80485666,0.031500585,0.0016676164,0.009551098],"study_design_scores_gemma":[0.00065043516,0.000076640885,0.003788728,0.00015700363,0.000008267899,0.000013357897,0.00024148276,0.20078465,0.79098386,0.0015380947,0.0015826174,0.00017487956],"about_ca_topic_score_codex":0.000012309467,"about_ca_topic_score_gemma":0.0001338166,"teacher_disagreement_score":0.060776178,"about_ca_system_score_codex":0.00006237174,"about_ca_system_score_gemma":0.00006126304,"threshold_uncertainty_score":0.42972234},"labels":[],"label_agreement":null},{"id":"W4206486961","doi":"10.1515/nanoph-2021-0775","title":"Nonlinear thermal lensing of high repetition rate ultrafast laser light in plasmonic nano‐colloids","year":2022,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Nonlinear Optical Materials Studies","field":"Engineering","cited_by":6,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Polytechnique Montréal","funders":"Natural Sciences and Engineering Research Council of Canada","keywords":"Plasmon; Ultrashort pulse; Nanomaterials; Materials science; Laser; Optics; Nano-; Thermal; Nonlinear system; Optoelectronics; Nonlinear optics; Repetition (rhetorical device); Nanotechnology; Physics","score_opus":0.005749481269208642,"score_gpt":0.1913624807874509,"score_spread":0.18561299951824228,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4206486961","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99712735,0.0001565635,0.0000045208117,0.00007967128,0.0008941214,0.00022521993,0.000106614425,0.00013335387,0.0012725871],"genre_scores_gemma":[0.9964483,0.00010289411,0.0031163245,0.000045051293,0.000039637904,0.000044986606,0.000027032329,0.000059293638,0.000116508214],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9987267,0.00007385067,0.0004287318,0.00021769201,0.00022585469,0.0003271525],"domain_scores_gemma":[0.9995113,0.00008616084,0.00006235298,0.00025884004,0.000043338678,0.000037979364],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00032717793,0.00018485382,0.00034660535,0.000096936405,0.00009827752,0.00001712235,0.00015696482,0.000072264884,0.0003108546],"category_scores_gemma":[0.00004879288,0.00019541314,0.000064967826,0.00035542814,0.00003970244,0.000078340185,0.00012415848,0.00024334638,0.000022467897],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00006916985,0.000091616464,0.00021438394,0.00008470453,0.000029013665,0.00002253316,0.00023426702,0.052269198,0.9467528,0.0001084297,0.000033486285,0.00009043507],"study_design_scores_gemma":[0.0007884552,0.000138586,0.0008988196,0.000045900506,0.000019600646,0.0000088704855,0.00013927105,0.013560105,0.97915554,0.000069896894,0.004926637,0.00024834438],"about_ca_topic_score_codex":0.000039154424,"about_ca_topic_score_gemma":0.000053186464,"teacher_disagreement_score":0.038709093,"about_ca_system_score_codex":0.00019379567,"about_ca_system_score_gemma":0.00004569748,"threshold_uncertainty_score":0.79687166},"labels":[],"label_agreement":null},{"id":"W4220654598","doi":"10.1515/nanoph-2022-0001","title":"Polarization‐dependent photonic crystal fiber optical filters enabled by asymmetric metasurfaces","year":2022,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":31,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Université Laval; Genia Photonics (Canada)","funders":"Air Force Office of Scientific Research; Baylor University","keywords":"Photonic-crystal fiber; Materials science; Polarization (electrochemistry); Optoelectronics; Polarization-maintaining optical fiber; Optics; Photonics; Optical fiber; Microstructured optical fiber; Plastic optical fiber; Optical filter; Wavelength; Fiber optic sensor; Physics","score_opus":0.01199720217895178,"score_gpt":0.2333190983018185,"score_spread":0.2213218961228667,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4220654598","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9920456,0.0017123355,0.00030381329,0.00022706421,0.00096077233,0.0007978475,0.0011318704,0.00017561593,0.0026450756],"genre_scores_gemma":[0.9580317,0.00013905986,0.029174075,0.0005732061,0.00002289875,0.00072069996,0.00037399773,0.00009003343,0.010874305],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9964913,0.0003208783,0.00067340344,0.0007606788,0.0010775436,0.00067617826],"domain_scores_gemma":[0.9983822,0.00016990838,0.00032906723,0.00077634363,0.000114534036,0.00022795972],"candidate_categories":["metaepi_narrow","insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.0017213172,0.00031829745,0.0005052838,0.00012889439,0.0009190223,0.0002546184,0.0008363649,0.00010422206,0.01906443],"category_scores_gemma":[0.00013013251,0.00030828812,0.00014620344,0.00088334386,0.00009419982,0.00022944597,0.0005027631,0.00026502545,0.0007299183],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000042950083,0.00022195031,0.000025910253,0.000019015712,0.000031447402,0.0000053069252,0.00008100528,0.0022716424,0.99249935,0.00051743496,0.0041339817,0.0001499865],"study_design_scores_gemma":[0.0005902485,0.000119508324,0.000030290408,0.0000028818247,0.00009736786,0.000025673371,0.00010612979,0.001339867,0.75454926,0.00012728863,0.24267603,0.00033546422],"about_ca_topic_score_codex":0.00018053468,"about_ca_topic_score_gemma":0.000005782415,"teacher_disagreement_score":0.23854205,"about_ca_system_score_codex":0.00025507403,"about_ca_system_score_gemma":0.00022973417,"threshold_uncertainty_score":0.99993694},"labels":[],"label_agreement":null},{"id":"W4220781019","doi":"10.1515/nanoph-2021-0718","title":"Gauge‐independent emission spectra and quantum correlations in the ultrastrong coupling regime of open system cavity‐QED","year":2022,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Strong Light-Matter Interactions","field":"Physics and Astronomy","cited_by":39,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Queen's University","funders":"Army Research Office; Core Research for Evolutional Science and Technology; Japan Science and Technology Agency; Foundational Questions Institute; Russian Foundation for Basic Research; Japan Society for the Promotion of Science; Moonshot Research and Development Program; Nippon Telegraph and Telephone; Asian Office of Aerospace Research and Development","keywords":"Physics; Cavity quantum electrodynamics; Quantum mechanics; Quantum electrodynamics; Gauge fixing; Gauge theory; Quantum; Gauge anomaly; Open quantum system; Introduction to gauge theory; Gauge boson","score_opus":0.015697479110326054,"score_gpt":0.2724263335882459,"score_spread":0.2567288544779199,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4220781019","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9939067,0.000052829157,0.0001984797,0.00020577735,0.00033562563,0.00058600865,0.00012936628,0.000013850843,0.0045713703],"genre_scores_gemma":[0.9991482,3.8645555e-7,0.00024225771,0.000016166809,0.000027788019,0.00014627136,0.000055648543,0.000017068895,0.00034622572],"study_design_codex":"observational","study_design_gemma":"qualitative","domain_scores_codex":[0.99884987,0.00008745547,0.000337009,0.0002474642,0.000274185,0.00020401074],"domain_scores_gemma":[0.99914783,0.00019826919,0.00022276618,0.0003554544,0.000033934633,0.00004172171],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00039880085,0.00012814862,0.00021085911,0.00006692425,0.0003541754,0.000091420225,0.00047989402,0.000024415596,0.00025187628],"category_scores_gemma":[0.000005758899,0.00011064152,0.0000611248,0.00024350442,0.00002769048,0.00014332039,0.00022038905,0.00043005042,0.000005469672],"study_design_candidate":"observational","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00030991627,0.0019399183,0.47430983,0.00017915003,0.00039811674,0.000054278647,0.015911316,0.028522694,0.3260519,0.142053,0.009630439,0.00063943997],"study_design_scores_gemma":[0.01187713,0.0012535773,0.19175676,0.001297461,0.00076897925,0.00038645734,0.33337533,0.2453832,0.17650366,0.0068103243,0.028039353,0.0025477957],"about_ca_topic_score_codex":0.001703563,"about_ca_topic_score_gemma":0.000026606995,"teacher_disagreement_score":0.317464,"about_ca_system_score_codex":0.00013853106,"about_ca_system_score_gemma":0.0001152145,"threshold_uncertainty_score":0.45118302},"labels":[],"label_agreement":null},{"id":"W4223580640","doi":"10.1515/nanoph-2022-0049","title":"Design automation of photonic resonator weights","year":2022,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Neural Networks and Reservoir Computing","field":"Computer Science","cited_by":31,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Vector Institute; Queen's University","funders":"","keywords":"Resonator; Photonics; Neuromorphic engineering; Electronic engineering; Computer science; Automation; Electronic circuit; Computer engineering; Electrical engineering; Engineering; Artificial intelligence; Materials science; Artificial neural network; Optoelectronics; Mechanical engineering","score_opus":0.06422354668248455,"score_gpt":0.2996503588930128,"score_spread":0.23542681221052825,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4223580640","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.000004743226,0.975926,0.021189366,0.000011236669,0.001323869,0.0009793625,0.000005678877,0.00019514083,0.00036463427],"genre_scores_gemma":[0.0000020809277,0.91501004,0.08451125,0.000030825195,0.000038609767,0.000107753986,0.00001560827,0.000041624564,0.00024222408],"study_design_codex":"design_other","study_design_gemma":"not_applicable","domain_scores_codex":[0.9965621,0.0005793801,0.0009414629,0.00074196607,0.0007095063,0.00046556364],"domain_scores_gemma":[0.9967795,0.00081705226,0.00096995465,0.0012652832,0.00006175726,0.00010644739],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0008575,0.00043772944,0.0013983616,0.00023778832,0.0002650417,0.00010601352,0.0027029677,0.00028814338,0.00013476379],"category_scores_gemma":[0.000038524,0.00034980508,0.00057930493,0.0014583193,0.00003899346,0.00017796182,0.0011439059,0.0006836504,0.00004000314],"study_design_candidate":"design_other","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0000017649952,0.0000648913,5.7855097e-8,0.0033539583,0.00007385034,0.000052988347,0.00007455116,0.000495317,0.0000043227483,0.002687121,0.00087264425,0.9923185],"study_design_scores_gemma":[0.0000913463,0.00010335245,6.41626e-8,0.001602127,0.00006610505,0.00004655261,0.000001053713,0.14458841,0.000040049086,0.00033758892,0.8528166,0.00030678534],"about_ca_topic_score_codex":0.000006879114,"about_ca_topic_score_gemma":4.8571684e-7,"teacher_disagreement_score":0.9920117,"about_ca_system_score_codex":0.00025282192,"about_ca_system_score_gemma":0.00077115715,"threshold_uncertainty_score":0.9998954},"labels":[],"label_agreement":null},{"id":"W4224107005","doi":"10.1515/nanoph-2022-0057","title":"Recent advances in optical label‐free characterization of extracellular vesicles","year":2022,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Extracellular vesicles in disease","field":"Biochemistry, Genetics and Molecular Biology","cited_by":44,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"McGill University","funders":"Fonds de recherche du Québec – Nature et technologies; Natural Sciences and Engineering Research Council of Canada; Faculty of Engineering, McGill University","keywords":"Extracellular vesicles; Characterization (materials science); Nanotechnology; Nanomaterials; Vesicle; Materials science; Chemistry; Biology; Cell biology; Biochemistry","score_opus":0.02389637446441893,"score_gpt":0.29704993202709584,"score_spread":0.2731535575626769,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4224107005","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.0035846794,0.9946493,0.000040482915,0.0000077020795,0.00032654707,0.000728871,0.00027705237,0.000013144121,0.00037222577],"genre_scores_gemma":[0.000031691357,0.9963379,0.00094675535,0.000020657131,0.000059177783,0.0001396781,0.0021234176,0.00009440041,0.00024633028],"study_design_codex":"design_other","study_design_gemma":"not_applicable","domain_scores_codex":[0.9975912,0.000237817,0.00085667626,0.00064425485,0.0003342648,0.0003357701],"domain_scores_gemma":[0.9982076,0.000043524058,0.00050966634,0.0010846122,0.000052505195,0.00010208135],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0004114286,0.00038294285,0.00085997727,0.000106718835,0.000048790207,0.000016285838,0.0008104345,0.00041769238,0.00020894098],"category_scores_gemma":[0.00029797573,0.00039525845,0.00026475708,0.0003890494,0.000110127214,0.000008912979,0.0004958787,0.00034099803,0.0000082194965],"study_design_candidate":"not_applicable","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000041692332,0.0003600169,0.0000052130176,0.0033453081,0.00004506079,0.000040867595,0.000012742565,0.000005450001,0.056037456,0.00016423983,0.000029935967,0.939912],"study_design_scores_gemma":[0.00036820176,0.00015027824,0.0000021018564,0.00063272787,0.00015093583,0.00001694313,0.000008548219,0.000028906623,0.008753664,0.00003608802,0.989486,0.00036560322],"about_ca_topic_score_codex":6.3898545e-7,"about_ca_topic_score_gemma":0.0000037519333,"teacher_disagreement_score":0.98945606,"about_ca_system_score_codex":0.00010018138,"about_ca_system_score_gemma":0.00050005154,"threshold_uncertainty_score":0.9998499},"labels":[],"label_agreement":null},{"id":"W4225273744","doi":"10.1515/nanoph-2022-0077","title":"Inducing optical self‐pulsation by electrically tuning graphene on a silicon microring","year":2022,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":5,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Queen's University","funders":"Natural Sciences and Engineering Research Council of Canada","keywords":"Graphene; Saturable absorption; Materials science; Optoelectronics; Silicon; Photonics; Absorption (acoustics); Optical switch; Silicon photonics; Nanotechnology; Fiber laser","score_opus":0.005818733047338841,"score_gpt":0.19697745435577835,"score_spread":0.1911587213084395,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4225273744","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.98480207,0.0008670178,0.0002890997,0.00006152608,0.00039282304,0.00024304668,0.000016793823,0.00054393697,0.012783687],"genre_scores_gemma":[0.9970817,0.00016822499,0.0021430957,0.0003209278,0.000024366853,0.00010414424,0.000031453957,0.000059620234,0.00006647967],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9984429,0.00003878706,0.00030078026,0.00032176843,0.00039581343,0.00049998274],"domain_scores_gemma":[0.99938136,0.00014994333,0.000040059724,0.0002656946,0.000025694046,0.0001372295],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00027249864,0.00021880821,0.00023382778,0.00011060216,0.0002662073,0.000055773955,0.0002690781,0.000104071674,0.00011884013],"category_scores_gemma":[0.000036605372,0.00024360034,0.00008984851,0.0005693414,0.000017720638,0.00010115232,0.00008683796,0.0007039915,0.000031885254],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000046012618,0.00019054873,0.00012813335,0.000062101586,0.00009752188,0.000029889836,0.00056629896,0.0227658,0.9664848,0.0040090685,0.0008716123,0.004748219],"study_design_scores_gemma":[0.001004853,0.0004965615,0.00035458815,0.000038425285,0.00006090453,0.000037836788,0.00018661325,0.61960596,0.3202809,0.00038462825,0.056800194,0.000748551],"about_ca_topic_score_codex":0.000011812762,"about_ca_topic_score_gemma":0.0000021843534,"teacher_disagreement_score":0.6462039,"about_ca_system_score_codex":0.00042549515,"about_ca_system_score_gemma":0.000050658964,"threshold_uncertainty_score":0.9933734},"labels":[],"label_agreement":null},{"id":"W4226059715","doi":"10.1515/nanoph-2021-0782","title":"Photoactive nanomaterials enabled integrated photo‐rechargeable batteries","year":2022,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Advanced Photocatalysis Techniques","field":"Energy","cited_by":23,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"McGill University; Hydro-Québec; Institut National de la Recherche Scientifique","funders":"Natural Sciences and Engineering Research Council of Canada; Canada Research Chairs","keywords":"Nanomaterials; Nanotechnology; Materials science","score_opus":0.043416118588537715,"score_gpt":0.3173450140949557,"score_spread":0.27392889550641797,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4226059715","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.00006181512,0.9710256,0.000041589865,0.00000271156,0.0016028759,0.0038094108,0.0012434239,0.001654352,0.020558264],"genre_scores_gemma":[0.0000047395774,0.97161937,0.005911517,0.00017702632,0.00009206472,0.010181427,0.0043887934,0.00064531015,0.0069797663],"study_design_codex":"design_other","study_design_gemma":"not_applicable","domain_scores_codex":[0.9928665,0.0009458016,0.0021267976,0.0018982765,0.0008481158,0.0013144921],"domain_scores_gemma":[0.994464,0.00078929774,0.0018007127,0.0025122212,0.00017304553,0.00026075053],"candidate_categories":["metaepi_narrow","insufficient_payload"],"consensus_categories":["metaepi_narrow"],"category_scores_codex":[0.0009264933,0.0018396234,0.005343827,0.000662571,0.000569822,0.00024928694,0.002038736,0.0011412866,0.0350165],"category_scores_gemma":[0.00041357373,0.0016518908,0.0014447258,0.0021384554,0.00021359899,0.00043373246,0.0009295707,0.0014540568,0.00066144543],"study_design_candidate":"not_applicable","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0003044027,0.00081684923,3.5997584e-7,0.017903088,0.0027803017,0.00064523297,0.0006186026,0.00003568478,0.008947072,0.0027104542,0.0077047753,0.9575332],"study_design_scores_gemma":[0.00029539663,0.00017096147,9.81228e-9,0.0019561748,0.0010083986,0.0001541321,0.00008060865,0.000027598024,0.04154826,0.0005236072,0.95268095,0.0015538819],"about_ca_topic_score_codex":0.0011576667,"about_ca_topic_score_gemma":0.00008984113,"teacher_disagreement_score":0.9559793,"about_ca_system_score_codex":0.0023260799,"about_ca_system_score_gemma":0.0013697325,"threshold_uncertainty_score":0.9994348},"labels":[],"label_agreement":null},{"id":"W4285589045","doi":"10.1515/nanoph-2022-0141","title":"Polymer modulators in silicon photonics: review and projections","year":2022,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":70,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Queen's University; University of British Columbia","funders":"British Columbia Knowledge Development Fund; Natural Sciences and Engineering Research Council of Canada; Canada Foundation for Innovation","keywords":"Silicon photonics; Materials science; Optical modulator; Photonics; Computer science; Voltage; Optoelectronics; CMOS; Electronic engineering; Phase modulation; Electrical engineering; Engineering","score_opus":0.02653011131157408,"score_gpt":0.28165262315010103,"score_spread":0.25512251183852697,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4285589045","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.000034322133,0.98904324,6.385102e-7,0.000008545505,0.0004592632,0.0016073559,0.00010788188,0.00023288035,0.008505905],"genre_scores_gemma":[0.0000051161924,0.9980419,0.00014446837,0.00015485975,0.00001170201,0.0011200141,0.00007945353,0.00014180841,0.0003006458],"study_design_codex":"design_other","study_design_gemma":"not_applicable","domain_scores_codex":[0.99776787,0.000092572074,0.0008254108,0.00054758333,0.00024949736,0.00051704707],"domain_scores_gemma":[0.9989605,0.00017296865,0.000118110635,0.0005875909,0.000013003599,0.00014782937],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00032064796,0.00059017574,0.0020086977,0.0002357591,0.000091132206,0.000039090603,0.00037314705,0.00035834848,0.0007753387],"category_scores_gemma":[0.00004494777,0.0005465366,0.0003355201,0.0010348101,0.00005776165,0.00010874709,0.00017292608,0.0011528494,0.00005238935],"study_design_candidate":"not_applicable","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0000025137092,0.00013602669,0.0000029015432,0.24748376,0.00043580306,0.00008776723,0.00013073643,0.000071893046,0.0000051205116,0.0011952608,0.0010740759,0.74937415],"study_design_scores_gemma":[0.00010821501,0.000026582315,5.15359e-7,0.007923108,0.0006721362,0.0000792253,0.000010118295,0.0029304184,0.0000061775872,0.000014555363,0.98767763,0.00055130763],"about_ca_topic_score_codex":0.00004698832,"about_ca_topic_score_gemma":0.000043998385,"teacher_disagreement_score":0.98660356,"about_ca_system_score_codex":0.0004531642,"about_ca_system_score_gemma":0.00026455187,"threshold_uncertainty_score":0.99969864},"labels":[],"label_agreement":null},{"id":"W4286499266","doi":"10.1515/nanoph-2022-0155","title":"Toward a universal metasurface for optical imaging, communication, and computation","year":2022,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":59,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Air Force Office of Scientific Research; Natural Sciences and Engineering Research Council of Canada; Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung","keywords":"Nanomaterials; Metamaterial; Computation; Computer science; Nanotechnology; Optics; Materials science; Optoelectronics; Physics","score_opus":0.030268089716469805,"score_gpt":0.2805013935834538,"score_spread":0.25023330386698395,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4286499266","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.98912543,0.0012541146,0.007026429,0.0010815051,0.00024668337,0.0006106382,0.0002152317,0.00007636747,0.0003635942],"genre_scores_gemma":[0.8350899,0.000086982436,0.16411617,0.00022346286,0.0000062247495,0.00023974919,0.00008343035,0.00001877311,0.00013527033],"study_design_codex":"bench_or_experimental","study_design_gemma":"not_applicable","domain_scores_codex":[0.99901366,0.00010259105,0.00023251973,0.00026447512,0.00019889734,0.0001878652],"domain_scores_gemma":[0.9992695,0.00015004109,0.0001316026,0.00028110307,0.00009954245,0.00006820495],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.0009509955,0.00010180439,0.00018853537,0.00002824183,0.0005782647,0.000089612004,0.00026820312,0.000021365126,0.00030961048],"category_scores_gemma":[0.000042331598,0.00010523871,0.000040608964,0.00011987022,0.00009069554,0.00010451844,0.00024442124,0.000069573754,0.000015117625],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00004206976,0.00006225938,0.000028828581,0.000021905178,0.000008926968,7.1375837e-7,0.00047047442,0.0018263948,0.9778185,0.017599842,0.001618576,0.0005015198],"study_design_scores_gemma":[0.0021781344,0.00018540127,0.00032011358,0.000009868247,0.00021943015,0.00006759765,0.0018320081,0.07434628,0.37705255,0.0092277555,0.5340186,0.00054227345],"about_ca_topic_score_codex":0.000055416374,"about_ca_topic_score_gemma":0.0000039641145,"teacher_disagreement_score":0.60076594,"about_ca_system_score_codex":0.000067586756,"about_ca_system_score_gemma":0.00008096232,"threshold_uncertainty_score":0.44476032},"labels":[],"label_agreement":null},{"id":"W4309045655","doi":"10.1515/nanoph-2022-0600","title":"Maximum electromagnetic local density of states via material structuring","year":2022,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":19,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Polytechnique Montréal","funders":"Defense Advanced Research Projects Agency; National Science Foundation","keywords":"Structuring; Nanomaterials; Metamaterial; Materials science; Nanotechnology; Optoelectronics; Business","score_opus":0.003211785855208783,"score_gpt":0.17652014930152718,"score_spread":0.1733083634463184,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4309045655","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99689436,0.00028505665,0.0007986621,0.000007416923,0.0005757761,0.00013056488,0.000054081407,0.0001424718,0.0011116063],"genre_scores_gemma":[0.9980526,0.00006501542,0.0017306716,0.00003650601,0.000011912924,0.00002024649,0.000026291884,0.00003147038,0.000025266796],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9989993,0.000024680721,0.00024227997,0.00015951552,0.0002497177,0.00032452279],"domain_scores_gemma":[0.9996354,0.000029187431,0.00003491888,0.00021216364,0.000022571943,0.00006573603],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.000100882025,0.00014152731,0.00022571483,0.00004268871,0.00008815029,0.000012666223,0.0002186832,0.000050503408,0.00083193136],"category_scores_gemma":[0.0000035950256,0.00015168027,0.000058521608,0.00016344964,0.0000534911,0.00004635282,0.00012520567,0.00021428865,0.000008712133],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00015131755,0.00006833981,0.0001449463,0.00030722204,0.00009980451,0.00007002501,0.0004354758,0.110275626,0.8814432,0.00094422494,0.0001404652,0.0059193415],"study_design_scores_gemma":[0.00034826619,0.00024867078,0.0006377964,0.0000061183464,0.000029021845,0.000049158192,0.00009741391,0.4289158,0.56277335,0.0035854452,0.0030666662,0.00024229278],"about_ca_topic_score_codex":0.00006118076,"about_ca_topic_score_gemma":0.000018025028,"teacher_disagreement_score":0.3186699,"about_ca_system_score_codex":0.000138991,"about_ca_system_score_gemma":0.000032749886,"threshold_uncertainty_score":0.9109065},"labels":[],"label_agreement":null},{"id":"W4313644474","doi":"10.1515/nanoph-2022-0795","title":"Erratum to: Gauge‐independent emission spectra and quantum correlations in the ultrastrong coupling regime of open system cavity‐QED","year":2023,"lang":"en","type":"erratum","venue":"Nanophotonics","topic":"Strong Light-Matter Interactions","field":"Physics and Astronomy","cited_by":0,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Queen's University","funders":"Japan Science and Technology Agency; Japan Society for the Promotion of Science; Army Research Office; Nippon Telegraph and Telephone; Asian Office of Aerospace Research and Development","keywords":"Physics; Coupling (piping); Gauge (firearms); Spectral line; Quantum; Nanomaterials; Cavity quantum electrodynamics; Quantum electrodynamics; Quantum mechanics; Condensed matter physics; Nanotechnology; Materials science; Open quantum system","score_opus":0.02128147473964538,"score_gpt":0.2959305991379584,"score_spread":0.274649124398313,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4313644474","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.6781323,0.00096866774,0.0013684618,0.0031936234,0.0912441,0.012126137,0.0044193678,0.00041304468,0.20813432],"genre_scores_gemma":[0.90131927,0.000011130787,0.00060760893,0.000054021933,0.0007797025,0.00054419914,0.0013722491,0.00020949484,0.09510232],"study_design_codex":"not_applicable","study_design_gemma":"not_applicable","domain_scores_codex":[0.99728566,0.000110530265,0.00082927995,0.0006973709,0.00056070293,0.00051645964],"domain_scores_gemma":[0.9978364,0.0003575662,0.00058816286,0.0009324031,0.0001430733,0.00014237883],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00058039156,0.00046167508,0.000753557,0.00025563213,0.00029316868,0.0003581628,0.0011751604,0.00028994502,0.00008747608],"category_scores_gemma":[0.00003622479,0.00038981534,0.00017981115,0.0006397903,0.00005438532,0.00020244381,0.0003765219,0.0016574806,0.00007782603],"study_design_candidate":"not_applicable","study_design_consensus":"not_applicable","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00005474455,0.00025446477,0.00472139,0.00027168533,0.00025166236,0.000030027351,0.0023794856,0.0008041386,0.0076761423,0.0046251807,0.9788597,0.000071366565],"study_design_scores_gemma":[0.010311236,0.0018480159,0.09375995,0.038084406,0.0032380281,0.00026820472,0.14089093,0.08821685,0.025960544,0.0075440495,0.5812719,0.008605945],"about_ca_topic_score_codex":0.0037708317,"about_ca_topic_score_gemma":0.00028908695,"teacher_disagreement_score":0.39758787,"about_ca_system_score_codex":0.00026777814,"about_ca_system_score_gemma":0.0005216006,"threshold_uncertainty_score":0.9998554},"labels":[],"label_agreement":null},{"id":"W4313814540","doi":"10.1515/nanoph-2022-0553","title":"Photonic online learning: a perspective","year":2023,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Neural Networks and Reservoir Computing","field":"Computer Science","cited_by":33,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Queen's University","funders":"Natural Sciences and Engineering Research Council of Canada; National Institute of Standards and Technology","keywords":"Neuromorphic engineering; Computer science; Perspective (graphical); Photonics; Computer architecture; Efficient energy use; Artificial neural network; Human–computer interaction; Artificial intelligence; Electrical engineering; Engineering; Physics","score_opus":0.01926823400906379,"score_gpt":0.2750197171007705,"score_spread":0.2557514830917067,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4313814540","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9821978,0.00075167115,0.005733231,0.0030261907,0.0013608625,0.00031563226,0.0000026971522,0.0021575962,0.004454321],"genre_scores_gemma":[0.97885615,0.00048171415,0.015467184,0.00048047822,0.000122161,0.000014347068,0.000008970098,0.0000327008,0.0045362962],"study_design_codex":"simulation_or_modeling","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9983467,0.000072026334,0.00019792553,0.00051492994,0.0003315685,0.00053685246],"domain_scores_gemma":[0.9990284,0.00015237533,0.0000871826,0.0004751806,0.000138435,0.0001184437],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00027225984,0.00016555958,0.00019004793,0.00011428596,0.00028970075,0.0001488737,0.0009633537,0.00008947549,0.000014619588],"category_scores_gemma":[0.00008768512,0.00014413297,0.0001257369,0.0017268223,0.000036447607,0.0001772896,0.0006782174,0.00044966047,0.00026785664],"study_design_candidate":"simulation_or_modeling","study_design_consensus":"simulation_or_modeling","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0000967247,0.0011255924,0.004293292,0.00017182964,0.00041069838,0.0030443915,0.017452234,0.49448937,0.064097255,0.2767504,0.033066858,0.10500135],"study_design_scores_gemma":[0.0002666805,0.00012505961,0.0006156338,0.000023090854,0.000003221324,0.000025772557,0.00024298752,0.9577077,0.0010890358,0.0028764755,0.03681329,0.00021106646],"about_ca_topic_score_codex":0.00004382213,"about_ca_topic_score_gemma":0.00001527365,"teacher_disagreement_score":0.4632183,"about_ca_system_score_codex":0.00009787748,"about_ca_system_score_gemma":0.00010180168,"threshold_uncertainty_score":0.5877572},"labels":[],"label_agreement":null},{"id":"W4313894114","doi":"10.1515/nanoph-2022-0485","title":"Photonic multiplexing techniques for neuromorphic computing","year":2023,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Neural Networks and Reservoir Computing","field":"Computer Science","cited_by":231,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut National de la Recherche Scientifique","funders":"National Natural Science Foundation of China","keywords":"Multiplexing; Photonics; Neuromorphic engineering; Computer science; Interconnectivity; Electronic engineering; Artificial neural network; Computer architecture; Telecommunications; Engineering; Artificial intelligence; Physics; Optoelectronics","score_opus":0.13286154797478134,"score_gpt":0.35274596029517424,"score_spread":0.2198844123203929,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4313894114","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.000003654219,0.9339133,0.05866502,0.00004238678,0.002174491,0.0028935391,0.000037577393,0.0021516893,0.00011833946],"genre_scores_gemma":[0.0000046900327,0.89464885,0.10415425,0.00013396812,0.00031917653,0.0002265041,0.000054743097,0.00019124044,0.00026657063],"study_design_codex":"design_other","study_design_gemma":"not_applicable","domain_scores_codex":[0.9954059,0.0002133816,0.0012637235,0.0014797453,0.000463176,0.0011740843],"domain_scores_gemma":[0.99549705,0.0017628869,0.000914292,0.0014599632,0.00016696611,0.00019883167],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0010650348,0.00082639983,0.0021498878,0.00033214744,0.00059189246,0.00055251096,0.0034770947,0.000604761,0.0000020496777],"category_scores_gemma":[0.00017180195,0.0006962374,0.0012100558,0.0017304331,0.00006348588,0.00019406292,0.00190643,0.0010057592,0.0000707862],"study_design_candidate":"design_other","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0000013524652,0.000032241027,1.5670047e-7,0.009795702,0.00008678972,0.000088453664,0.000035421555,0.00019490697,0.000006712904,0.0013420277,0.0009817386,0.9874345],"study_design_scores_gemma":[0.0001065198,0.00008505455,5.2757443e-8,0.0083372,0.00006763696,0.00008552396,0.0000012503459,0.27056745,0.000025798121,0.00023488162,0.71993417,0.00055448274],"about_ca_topic_score_codex":0.000014550054,"about_ca_topic_score_gemma":0.0000057192806,"teacher_disagreement_score":0.98688,"about_ca_system_score_codex":0.00018936003,"about_ca_system_score_gemma":0.00052393664,"threshold_uncertainty_score":0.99954885},"labels":[],"label_agreement":null},{"id":"W4316034760","doi":"10.1515/nanoph-2022-0502","title":"Spin–orbit coupling induced by ascorbic acid crystals","year":2023,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Orbital Angular Momentum in Optics","field":"Physics and Astronomy","cited_by":2,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"National Research Council Canada; University of Ottawa","funders":"Canada First Research Excellence Fund; Canada Research Chairs","keywords":"Ascorbic acid; Spin–orbit interaction; Nanomaterials; Coupling (piping); Spin (aerodynamics); Materials science; Condensed matter physics; Chemical physics; Orbit (dynamics); Nanotechnology; Chemistry; Physics; Composite material; Aerospace engineering","score_opus":0.013526947172114672,"score_gpt":0.2600380699078928,"score_spread":0.24651112273577813,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4316034760","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99225134,0.00014067539,0.00014857322,0.0001561922,0.00060008804,0.0002871758,0.00011295541,0.0002127329,0.006090254],"genre_scores_gemma":[0.9963779,0.000018516514,0.0004678814,0.00008132062,0.000111838395,0.00006053458,0.00019540748,0.00006597508,0.0026206302],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99838287,0.000013529294,0.00031996536,0.0003740065,0.00034792503,0.0005616855],"domain_scores_gemma":[0.9991743,0.000044552948,0.00012618411,0.00044051697,0.00007008549,0.00014435028],"candidate_categories":["metaepi_narrow","insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.00021849535,0.00025105954,0.00026780192,0.000072543175,0.00018111957,0.00011051336,0.00031066767,0.00009857414,0.0005660886],"category_scores_gemma":[0.000013099471,0.00025883754,0.00014791447,0.00060353446,0.000041058258,0.00013891008,0.00019488858,0.00028270457,0.0011710993],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000010603921,0.00014472849,0.0021314076,0.00003176783,0.00011236179,0.000011922484,0.00025033983,0.00023898939,0.98162234,0.0050132386,0.009303617,0.0011286942],"study_design_scores_gemma":[0.0017107251,0.0003161224,0.0006603059,0.00011161151,0.00010041608,0.0000027956255,0.0012660204,0.04123733,0.8638502,0.008504264,0.08093227,0.0013079843],"about_ca_topic_score_codex":0.00007206648,"about_ca_topic_score_gemma":0.0000014851943,"teacher_disagreement_score":0.11777217,"about_ca_system_score_codex":0.00006218033,"about_ca_system_score_gemma":0.000097961594,"threshold_uncertainty_score":0.9999864},"labels":[],"label_agreement":null},{"id":"W4317513914","doi":"10.1515/nanoph-2022-0630","title":"Surface plasmon mediated harmonically resonant effects on third harmonic generation from Au and CuS nanoparticle films","year":2023,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Gold and Silver Nanoparticles Synthesis and Applications","field":"Materials Science","cited_by":19,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Vanderbilt Institute of Nanoscale Science and Engineering, Vanderbilt University; Fulbright Canada; Vanderbilt University; National Science Foundation","keywords":"Materials science; Plasmon; Nanoparticle; Second-harmonic generation; Surface plasmon resonance; Optoelectronics; Plasmonic nanoparticles; Harmonics; Photon upconversion; Nanotechnology; Nonlinear optics; Surface plasmon; Excitation; High harmonic generation; Optics; Doping; Physics; Laser","score_opus":0.026255577246510845,"score_gpt":0.2462819795748647,"score_spread":0.22002640232835385,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4317513914","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99719596,0.00029203575,0.000005902866,0.0012852049,0.00036164644,0.0003734542,0.00010783381,0.00027963961,0.0000983284],"genre_scores_gemma":[0.9977792,0.00030150832,0.0011209898,0.0003584959,0.000055837045,0.000083702005,0.000052044245,0.00003054957,0.00021769541],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9980182,0.00013482494,0.00036213268,0.00058558077,0.00038559883,0.0005136613],"domain_scores_gemma":[0.99853384,0.00064572465,0.00011405342,0.00044381636,0.00005179731,0.00021075766],"candidate_categories":["insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.0005235744,0.00021934115,0.00028098788,0.0000338647,0.00038335737,0.00015435094,0.00023717002,0.00014145674,0.00009249651],"category_scores_gemma":[0.00017579195,0.00018153017,0.000063708685,0.0003558715,0.000083478764,0.00012807273,0.000109856184,0.00012769108,0.0014247157],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0000442722,0.00007625716,0.00058234046,0.000008472856,0.000008540278,0.000014156235,0.00027185897,0.0001551175,0.9943351,0.00053832255,0.0032149341,0.0007506227],"study_design_scores_gemma":[0.00061703456,0.00013365073,0.0048252204,0.000039001246,0.000028217557,0.0000012458942,0.0000405825,0.038416833,0.95149624,0.00020050813,0.0039793947,0.00022207286],"about_ca_topic_score_codex":0.00025660975,"about_ca_topic_score_gemma":0.00009827738,"teacher_disagreement_score":0.042838868,"about_ca_system_score_codex":0.00006779149,"about_ca_system_score_gemma":0.0001204568,"threshold_uncertainty_score":0.9993528},"labels":[],"label_agreement":null},{"id":"W4318049701","doi":"10.1515/nanoph-2022-0670","title":"Advances in electrochromic device technology through the exploitation of nanophotonic and nanoplasmonic effects","year":2023,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Transition Metal Oxide Nanomaterials","field":"Materials Science","cited_by":27,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Alberta","funders":"Natural Sciences and Engineering Research Council of Canada","keywords":"Nanophotonics; Electrochromism; Nanomaterials; Materials science; Nanotechnology; Electrochromic devices; Plasmon; Optoelectronics; Chemistry; Electrode","score_opus":0.024702128237865897,"score_gpt":0.3246838905524074,"score_spread":0.2999817623145415,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4318049701","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.06715394,0.9293563,0.000014965577,0.000024502138,0.0008964083,0.0022116944,0.00007102614,0.00020559685,0.000065577195],"genre_scores_gemma":[0.0012878489,0.9951012,0.0022938207,0.000030924755,0.000017871746,0.0010637884,0.000028354309,0.00013082639,0.000045328627],"study_design_codex":"bench_or_experimental","study_design_gemma":"not_applicable","domain_scores_codex":[0.99588853,0.00054736057,0.00152972,0.00089201855,0.00044836398,0.0006940223],"domain_scores_gemma":[0.99676037,0.0012136956,0.0010730581,0.0007995417,0.000102417085,0.00005091134],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0009676995,0.0006542779,0.0025143514,0.00044040827,0.0001390127,0.000072734496,0.0008573422,0.0007475291,0.000041318017],"category_scores_gemma":[0.00032211412,0.0004678856,0.00025842118,0.002128008,0.00040481953,0.0004375213,0.00020259467,0.00041083936,0.00023488532],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00010205978,0.00020154743,0.0000029569514,0.09577004,0.00013347292,0.00011977546,0.00094806793,0.000039856455,0.76038903,0.006076012,0.000036761416,0.13618045],"study_design_scores_gemma":[0.0013021004,0.0005743885,0.0000046565888,0.027306084,0.0009794955,0.00023266702,0.00021447541,0.000027405516,0.33666736,0.0057215765,0.6257478,0.0012219949],"about_ca_topic_score_codex":0.000036715173,"about_ca_topic_score_gemma":0.00014922312,"teacher_disagreement_score":0.625711,"about_ca_system_score_codex":0.00026605744,"about_ca_system_score_gemma":0.00060468627,"threshold_uncertainty_score":0.99977726},"labels":[],"label_agreement":null},{"id":"W4353044837","doi":"10.1515/nanoph-2022-0756","title":"Time‐varying gradient metasurface with applications in all‐optical beam steering","year":2023,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":20,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Ottawa","funders":"Army Research Office; Office of Naval Research; Multidisciplinary University Research Initiative; Defense Advanced Research Projects Agency; Ministère de la Défense Nationale; Canada Research Chairs; U.S. Department of Energy; National Science Foundation","keywords":"Diffraction; Beam steering; Materials science; Diffraction efficiency; Optics; Plasmon; Indium tin oxide; Wavelength; Optoelectronics; Grating; Diffraction grating; Thin film; Beam (structure); Physics; Nanotechnology","score_opus":0.02965121620105211,"score_gpt":0.2717025948589215,"score_spread":0.2420513786578694,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4353044837","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99718845,0.00017650754,0.0003465604,0.00014658207,0.00012467352,0.0008402238,0.000056689176,0.00028666103,0.00083366066],"genre_scores_gemma":[0.953325,0.00021591893,0.044210322,0.000117946445,0.00002759133,0.0011299637,0.00012804313,0.00007769613,0.0007675431],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9981218,0.00004755824,0.00041149353,0.00051604316,0.0003692816,0.0005338402],"domain_scores_gemma":[0.9989328,0.00013987739,0.00011928753,0.0005992608,0.00006270674,0.00014606901],"candidate_categories":["insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.0009407573,0.00021218645,0.00036491995,0.000099369,0.0001694108,0.00010357973,0.00037304751,0.00008663527,0.0002629888],"category_scores_gemma":[0.000032763175,0.00017286232,0.000052136318,0.0008375106,0.00009853846,0.00014017556,0.00012485663,0.000115517345,0.0017510982],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000014666267,0.00006257226,0.000057855505,0.000028522485,0.000011498186,0.0000051099632,0.00020904162,0.010168579,0.9882121,0.0010403314,0.0000963412,0.00009335436],"study_design_scores_gemma":[0.00045857072,0.000058481994,0.00062401063,0.000030587606,0.00006319989,0.000008618999,0.0001216763,0.0053886226,0.94015807,0.00023575648,0.052521218,0.00033120473],"about_ca_topic_score_codex":0.000047485275,"about_ca_topic_score_gemma":0.000024239447,"teacher_disagreement_score":0.052424878,"about_ca_system_score_codex":0.000080268226,"about_ca_system_score_gemma":0.000078961224,"threshold_uncertainty_score":0.9990262},"labels":[],"label_agreement":null},{"id":"W4360605022","doi":"10.1515/nanoph-2022-0783","title":"A chiral microchip laser using anisotropic grating mirrors for single mode emission","year":2023,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photorefractive and Nonlinear Optics","field":"Physics and Astronomy","cited_by":7,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Université de Moncton","funders":"H2020 Marie Skłodowska-Curie Actions; Natural Sciences and Engineering Research Council of Canada; Agence Nationale de la Recherche; New Brunswick Innovation Foundation","keywords":"Materials science; Grating; Optics; Laser; Nanomaterials; Optoelectronics; Single-mode optical fiber; Anisotropy; Mode (computer interface); Nanotechnology; Physics; Computer science","score_opus":0.051581737252506386,"score_gpt":0.3318591403827716,"score_spread":0.2802774031302652,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4360605022","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9970467,0.000018144272,0.0012299055,0.000025417708,0.00024591095,0.0003038866,0.00024570347,0.00006878807,0.00081555825],"genre_scores_gemma":[0.9798792,0.0000033341669,0.018611867,0.000058844125,0.00014767789,0.000031964973,0.0002065144,0.000053185726,0.0010074095],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99900234,0.000019693376,0.00020866383,0.00026481095,0.00012459849,0.0003799076],"domain_scores_gemma":[0.9994529,0.00007664421,0.000113877235,0.00019761488,0.0000751532,0.00008383219],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00008752423,0.00017369862,0.0001946836,0.00005454996,0.00025716276,0.000049439615,0.00012915074,0.000067733745,0.000034993456],"category_scores_gemma":[0.000015359055,0.000165789,0.00014548743,0.0002655339,0.000024396071,0.000110433444,0.00006244617,0.00013579593,0.000021527183],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000035662757,0.00010617661,0.0021636395,0.000020787918,0.00003333668,0.0000021938065,0.00026629335,0.00016351503,0.9963435,0.00015784855,0.00021989403,0.00048716422],"study_design_scores_gemma":[0.0007167946,0.00009221683,0.000049696722,0.000046488774,0.00003830568,0.0000012394552,0.0003356641,0.16134335,0.82635546,0.0024677874,0.008303341,0.0002496756],"about_ca_topic_score_codex":0.00009595288,"about_ca_topic_score_gemma":0.000005125016,"teacher_disagreement_score":0.16998805,"about_ca_system_score_codex":0.0000514483,"about_ca_system_score_gemma":0.00010475431,"threshold_uncertainty_score":0.6760679},"labels":[],"label_agreement":null},{"id":"W4364379033","doi":"10.1515/nanoph-2023-0120","title":"Enhanced cutoff energies for direct and rescattered strong‐field photoelectron emission of plasmonic nanoparticles","year":2023,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Gold and Silver Nanoparticles Synthesis and Applications","field":"Materials Science","cited_by":6,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut National de la Recherche Scientifique","funders":"SLAC National Accelerator Laboratory; Air Force Office of Scientific Research; Chemical Sciences, Geosciences, and Biosciences Division; Basic Energy Sciences; U.S. Air Force; Strong; U.S. Department of Energy; Office of Science; National Science Foundation","keywords":"Plasmon; Nanomaterials; Nanoparticle; Cutoff; Field electron emission; Materials science; Field (mathematics); X-ray photoelectron spectroscopy; Nanotechnology; Optoelectronics; Physics; Nuclear magnetic resonance; Electron; Quantum mechanics","score_opus":0.01650197133579578,"score_gpt":0.2621561477122973,"score_spread":0.2456541763765015,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4364379033","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99869144,0.0002545478,0.000022536737,0.00021634415,0.00009607013,0.00031176463,0.000046921134,0.000121373596,0.00023902775],"genre_scores_gemma":[0.9983367,0.0002645131,0.0007689776,0.00004625151,0.000014110347,0.00018670494,0.0000075650732,0.000018707755,0.00035647512],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99880344,0.0000313887,0.00030909476,0.00032614937,0.00016506379,0.00036485912],"domain_scores_gemma":[0.99911106,0.00034912096,0.00012030376,0.0002806809,0.000060708186,0.000078120655],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00029437937,0.00013460213,0.00025307058,0.0000503163,0.00017638085,0.000045164714,0.00017679072,0.00007943396,0.00004982825],"category_scores_gemma":[0.00009985648,0.00011475388,0.00007007629,0.00023830091,0.000066683155,0.000088486784,0.00006786667,0.000041215928,0.000018871273],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00008551889,0.000045845532,0.000083229286,0.000040090767,0.000006571776,3.4046676e-7,0.00019808153,0.00007043539,0.9967051,0.00063053996,0.0007420329,0.0013921739],"study_design_scores_gemma":[0.00036683682,0.00019081253,0.00022253284,0.000043765656,0.000024401017,7.860298e-7,0.00014337708,0.0020157134,0.9945995,0.00034753862,0.0019097424,0.00013497226],"about_ca_topic_score_codex":0.000036237867,"about_ca_topic_score_gemma":0.000016737438,"teacher_disagreement_score":0.0021056181,"about_ca_system_score_codex":0.000019027868,"about_ca_system_score_gemma":0.000061020335,"threshold_uncertainty_score":0.46795273},"labels":[],"label_agreement":null},{"id":"W4365446997","doi":"10.1515/nanoph-2022-0820","title":"Asymmetric transmission in nanophotonics","year":2023,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":41,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Alberta","funders":"Natural Sciences and Engineering Research Council of Canada; Alberta Innovates","keywords":"Nanophotonics; Nanomaterials; Transmission (telecommunications); Nanotechnology; Materials science; Optoelectronics; Computer science; Telecommunications","score_opus":0.05528226104386673,"score_gpt":0.3195548816013447,"score_spread":0.26427262055747797,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4365446997","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.00009004975,0.9910858,0.000028293021,0.0000044560306,0.00082878844,0.0012498026,0.0001337764,0.00075970317,0.005819295],"genre_scores_gemma":[0.0000014240026,0.99271774,0.0043111015,0.000006717296,0.000005549762,0.0003263239,0.00014904761,0.00037580685,0.0021062598],"study_design_codex":"design_other","study_design_gemma":"not_applicable","domain_scores_codex":[0.99594647,0.00013438814,0.0012099926,0.0007009564,0.00077306805,0.0012351391],"domain_scores_gemma":[0.9980186,0.0007751727,0.00010445315,0.00075083517,0.00004443296,0.00030647105],"candidate_categories":["metaepi_narrow","research_integrity","insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.000870465,0.00084434514,0.0024527458,0.0013000403,0.00007934758,0.0000943713,0.0009788389,0.0013915176,0.000093899514],"category_scores_gemma":[0.00011064452,0.00076867116,0.00065550354,0.0048769666,0.000052771193,0.00010650312,0.00012664289,0.002027974,0.0019838742],"study_design_candidate":"design_other","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0000062383056,0.00006787928,0.0000013805748,0.03610067,0.00023252281,0.0005189432,0.00005937374,0.0042400956,0.000008545457,0.000049419923,0.0045684376,0.9541465],"study_design_scores_gemma":[0.00026909506,0.000029275823,6.4088516e-7,0.0070917103,0.00011750809,0.000024871806,0.000007600149,0.082353435,0.000023284198,0.000039102237,0.9093633,0.0006801677],"about_ca_topic_score_codex":0.000023756254,"about_ca_topic_score_gemma":0.000032198794,"teacher_disagreement_score":0.9534663,"about_ca_system_score_codex":0.0008512261,"about_ca_system_score_gemma":0.0006786688,"threshold_uncertainty_score":0.9999049},"labels":[],"label_agreement":null},{"id":"W4365458379","doi":"10.1515/nanoph-2023-0177","title":"High numerical aperture imaging allows chirality measurement in individual collagen fibrils using polarization second harmonic generation microscopy","year":2023,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Advanced Fluorescence Microscopy Techniques","field":"Biochemistry, Genetics and Molecular Biology","cited_by":25,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Dalhousie University; University of Toronto; Saint Mary's University","funders":"Natural Sciences and Engineering Research Council of Canada; European Regional Development Fund; Canada Foundation for Innovation; Research Nova Scotia; Saint Mary’s University","keywords":"Microscopy; Materials science; Numerical aperture; Optics; Polarization (electrochemistry); Second-harmonic generation; Microscope; Fibril; Optical microscope; Nanoscopic scale; Polarized light microscopy; Collagen fibril; Molecular physics; Nanotechnology; Biophysics; Optoelectronics; Chemistry; Scanning electron microscope; Physics; Laser; Composite material","score_opus":0.032780433190973096,"score_gpt":0.3024238894147192,"score_spread":0.2696434562237461,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4365458379","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.98279554,0.00070086244,0.0154911205,0.00009288419,0.00021611655,0.0005059982,0.0001071964,0.00007638053,0.000013883463],"genre_scores_gemma":[0.93102264,0.00012731981,0.067111276,0.0006200187,0.00008558645,0.000044731874,0.00086439267,0.00005582026,0.000068198395],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9982929,0.000098072785,0.0003509054,0.000541531,0.00030498556,0.0004116022],"domain_scores_gemma":[0.9993149,0.000007775714,0.00013044743,0.00035439027,0.00012678318,0.00006567312],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0004768548,0.00023132456,0.00020645495,0.00009065196,0.0001380047,0.000071165116,0.00022709655,0.00022748108,0.000021643731],"category_scores_gemma":[0.00013226077,0.00025471067,0.00006864051,0.00043101568,0.000055084787,0.000020421303,0.00016903017,0.00012788436,0.00000803829],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00002871027,0.000033134096,0.004858751,0.000017260309,0.000016891512,0.000005952404,0.000071457085,0.00024103656,0.9938137,0.000007648024,0.0006863609,0.00021912603],"study_design_scores_gemma":[0.00041195596,0.00006303349,0.0022205904,0.00002799289,0.000012838005,0.0000075364737,0.000022713217,0.008435888,0.9825871,0.000036342037,0.0058999853,0.00027403235],"about_ca_topic_score_codex":0.00006364847,"about_ca_topic_score_gemma":0.00009308826,"teacher_disagreement_score":0.0517729,"about_ca_system_score_codex":0.00020221925,"about_ca_system_score_gemma":0.00024584337,"threshold_uncertainty_score":0.9999905},"labels":[],"label_agreement":null},{"id":"W4381660974","doi":"10.1515/nanoph-2023-0231","title":"Resonant inelastic tunneling using multiple metallic quantum wells","year":2023,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Quantum and electron transport phenomena","field":"Physics and Astronomy","cited_by":0,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Université de Sherbrooke","funders":"National Key Research and Development Program of China; National Natural Science Foundation of China","keywords":"Quantum tunnelling; Nanomaterials; Quantum well; Metal; Quantum; Materials science; Physics; Optoelectronics; Nanotechnology; Quantum mechanics; Laser; Metallurgy","score_opus":0.024246025616373332,"score_gpt":0.2525574820697263,"score_spread":0.22831145645335293,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4381660974","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99547225,0.00023101777,0.0028688905,0.0000469701,0.0004128541,0.00021878774,0.000050915147,0.00016591401,0.000532389],"genre_scores_gemma":[0.99856836,0.000036892867,0.0006293725,0.000045509765,0.00010422754,0.0000242395,0.00009916365,0.000060174425,0.00043205477],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9982504,0.000034000223,0.000369553,0.00038549257,0.00025389675,0.0007066596],"domain_scores_gemma":[0.99925727,0.00012270712,0.00010609991,0.0003229442,0.000053707794,0.00013729505],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.000274889,0.0002487367,0.00031664682,0.000112717884,0.00024383851,0.000048355752,0.00022872418,0.00006724749,0.00039273873],"category_scores_gemma":[0.000009345364,0.000234457,0.00017763021,0.0006974732,0.000044607674,0.00011957381,0.00004523914,0.00027335726,0.00047226218],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00028351095,0.0008133606,0.0758353,0.00025926865,0.0008756799,0.00011552743,0.0030956576,0.031637084,0.76303375,0.11522904,0.0017630857,0.007058717],"study_design_scores_gemma":[0.0014489416,0.00011773655,0.0012479229,0.00008182447,0.00015275643,0.0000027838346,0.0006049448,0.9219179,0.020913383,0.015410709,0.03734769,0.00075340277],"about_ca_topic_score_codex":0.00034171736,"about_ca_topic_score_gemma":0.0000086438295,"teacher_disagreement_score":0.89028084,"about_ca_system_score_codex":0.000044293258,"about_ca_system_score_gemma":0.00015522783,"threshold_uncertainty_score":0.9560878},"labels":[],"label_agreement":null},{"id":"W4387378217","doi":"10.1515/nanoph-2023-0524","title":"Temperature‐insensitive and low‐loss single‐mode silicon waveguide crossing covering all optical communication bands enabled by curved anisotropic metamaterial","year":2023,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":17,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"McGill University","funders":"CMC Microsystems","keywords":"Materials science; Insertion loss; Silicon on insulator; Cladding (metalworking); Optics; Grating; Wavelength; Optoelectronics; Waveguide; Metamaterial; Anisotropy; Refractive index; Power dividers and directional couplers; Silicon; Bandwidth (computing); Physics; Telecommunications; Computer science","score_opus":0.010089381072915434,"score_gpt":0.23352733457438457,"score_spread":0.22343795350146914,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4387378217","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9956384,0.0008744386,0.000046442565,0.000083164385,0.00038273702,0.00025255172,0.00009186952,0.0005666936,0.0020637356],"genre_scores_gemma":[0.9970415,0.0010455586,0.0012703645,0.00016080939,0.00003512787,0.000028094262,0.00021450614,0.00007473805,0.00012929663],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9983237,0.0000674096,0.0004125959,0.0003564442,0.00025933847,0.0005805384],"domain_scores_gemma":[0.99901724,0.00023321857,0.00005294932,0.00043508844,0.000076692326,0.00018483461],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00026945517,0.0003232379,0.0004393447,0.00006759957,0.00027444944,0.00049816095,0.00022128009,0.00029822497,0.000022524631],"category_scores_gemma":[0.00009442349,0.00032112675,0.00007940947,0.00029471985,0.00021009776,0.0002974183,0.00016261233,0.00033170686,0.00004230762],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00004675335,0.000031910142,0.000029030529,0.00012628717,0.00008609084,0.0000295206,0.00044927024,0.0017134662,0.9967079,0.00039854756,0.00020875454,0.000172455],"study_design_scores_gemma":[0.0010599003,0.00007030317,0.000546376,0.00012924409,0.00006188373,0.000024039513,0.00010905353,0.2731827,0.7177406,0.00014908717,0.0064949133,0.00043190928],"about_ca_topic_score_codex":0.00005985027,"about_ca_topic_score_gemma":0.000045231976,"teacher_disagreement_score":0.2789673,"about_ca_system_score_codex":0.0001785084,"about_ca_system_score_gemma":0.00005078235,"threshold_uncertainty_score":0.99992406},"labels":[],"label_agreement":null},{"id":"W4387577935","doi":"10.1515/nanoph-2023-0301","title":"Microfluidics on lensless, semiconductor optical image sensors: challenges and opportunities for democratization of biosensing at the micro‐and nano‐scale","year":2023,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Advanced Fluorescence Microscopy Techniques","field":"Biochemistry, Genetics and Molecular Biology","cited_by":10,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"McGill University","funders":"Natural Sciences and Engineering Research Council of Canada; Faculty of Engineering, McGill University","keywords":"Microfluidics; Nanotechnology; Holography; Image sensor; Materials science; Photodiode; Microlens; Pixel; Computer science; Optoelectronics; Optics; Lens (geology); Physics","score_opus":0.0853843717092207,"score_gpt":0.34030910095005823,"score_spread":0.25492472924083753,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4387577935","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.0101886615,0.98788613,0.00012612701,0.000117736025,0.00011338017,0.0010941436,0.00040218365,0.000034211687,0.00003742319],"genre_scores_gemma":[0.000016687196,0.9862975,0.012567057,0.00005937396,0.000056303485,0.00006913758,0.0003588972,0.00011905785,0.00045602338],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99841624,0.00009762018,0.0004922626,0.00058828713,0.00011410016,0.0002915099],"domain_scores_gemma":[0.99880457,0.00016667506,0.0003274762,0.00048795238,0.00014874863,0.000064552754],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00031027143,0.00041305833,0.00076767866,0.000066717235,0.0001520182,0.000028158645,0.00017779658,0.0005846264,8.5125026e-7],"category_scores_gemma":[0.0001332855,0.00031448842,0.00017597535,0.00005836523,0.0005453003,0.0000060027814,0.00029270875,0.00016832702,0.0000012753732],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000026408054,0.000017404305,2.0243958e-7,0.0043438566,0.00006991932,0.0000026537705,0.000054859294,9.0348465e-8,0.90069795,0.000065284294,0.0005883693,0.09413298],"study_design_scores_gemma":[0.00010659524,0.00015825356,1.5570829e-7,0.0017097307,0.00015673181,0.00005015603,0.00009757026,0.000004890834,0.61378217,0.000032798584,0.38366348,0.00023747182],"about_ca_topic_score_codex":0.0000011008658,"about_ca_topic_score_gemma":0.000006955181,"teacher_disagreement_score":0.38307512,"about_ca_system_score_codex":0.000048166145,"about_ca_system_score_gemma":0.0001488416,"threshold_uncertainty_score":0.99993074},"labels":[],"label_agreement":null},{"id":"W4390741104","doi":"10.1515/nanoph-2023-0687","title":"Modeling with graded interfaces: Tool for understanding and designing record‐high power and efficiency mid‐infrared quantum cascade lasers","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Spectroscopy and Laser Applications","field":"Chemistry","cited_by":14,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Nexen (Canada)","funders":"Naval Air Systems Command; National Institute of Environmental Health Sciences; U.S. Navy; University of Wisconsin-Madison","keywords":"Cascade; Optoelectronics; Nanomaterials; Infrared; Quantum; Laser; Materials science; Quantum cascade laser; Power (physics); Computer science; Nanotechnology; Optics; Physics; Engineering","score_opus":0.023294711973270998,"score_gpt":0.25930719073400715,"score_spread":0.23601247876073617,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4390741104","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.86783844,0.0010779578,0.1299356,0.000080111546,0.00007836751,0.0002307235,0.000032767362,0.00015881615,0.0005671921],"genre_scores_gemma":[0.9923506,0.00017706136,0.007046536,0.000037513226,0.000015161166,0.000106960455,0.000015114034,0.00004683004,0.00020423379],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99888384,0.000007705236,0.00021412471,0.0004638926,0.00012939991,0.00030103666],"domain_scores_gemma":[0.999445,0.00020842795,0.00003815023,0.00020378237,0.00002748193,0.000077113174],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00014062886,0.00019783777,0.00018708565,0.00005775002,0.00024923513,0.0002003818,0.000103274084,0.00013577183,0.00004678548],"category_scores_gemma":[0.000026659825,0.00017420735,0.000036665235,0.00017936819,0.00007507596,0.00012870462,0.00003583579,0.00021970925,0.0000017332675],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00041497112,0.000086125656,0.00013262183,0.0009818437,0.00021860996,0.000027714275,0.0051729507,0.0045346576,0.9559951,0.031964447,0.00021281645,0.00025814306],"study_design_scores_gemma":[0.0007640446,0.00013752014,0.0000014432725,0.00040434516,0.000114962255,0.00003360533,0.0036695637,0.7173545,0.26607308,0.010527765,0.0005532089,0.00036598957],"about_ca_topic_score_codex":0.000041613235,"about_ca_topic_score_gemma":0.00002252427,"teacher_disagreement_score":0.7128198,"about_ca_system_score_codex":0.00017321267,"about_ca_system_score_gemma":0.000098143355,"threshold_uncertainty_score":0.71039695},"labels":[],"label_agreement":null},{"id":"W4391168152","doi":"10.1515/nanoph-2023-0606","title":"Can photonic heterostructures provably outperform single‐material geometries?","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Thermal Radiation and Cooling Technologies","field":"Engineering","cited_by":4,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Polytechnique Montréal","funders":"Defense Sciences Office, DARPA; Division of Materials Research; Materials Research Science and Engineering Center, Harvard University; Institut de Valorisation des Données; Cornell Center for Materials Research; Defense Advanced Research Projects Agency; Division of Emerging Frontiers; Princeton University; Division of Emerging Frontiers in Research and Innovation; Advanced Research Projects Agency; National Science Foundation","keywords":"Photonics; Heterojunction; Computer science; Inverse; Photonic crystal; Range (aeronautics); Absorption (acoustics); Fabrication; Materials science; Nanotechnology; Topology (electrical circuits); Electronic engineering; Optoelectronics; Mathematics; Engineering; Electrical engineering; Geometry","score_opus":0.007818997693439215,"score_gpt":0.19628236695536636,"score_spread":0.18846336926192714,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4391168152","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9896937,0.0017813491,0.00004905904,0.0000847342,0.0029233594,0.00019895796,0.00011139901,0.0034626825,0.0016947549],"genre_scores_gemma":[0.99853444,0.0002735581,0.0007290361,0.000064773805,0.00006043842,0.000039764345,0.000024323586,0.00006696323,0.0002066945],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9990146,0.000005088334,0.00022282395,0.00022246805,0.00018030954,0.0003547189],"domain_scores_gemma":[0.99957347,0.000026878848,0.000018254428,0.00030280594,0.00002373177,0.000054858658],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00007560606,0.00021372196,0.0001814203,0.00018175688,0.00006448984,0.0002518896,0.00025895258,0.00021036633,0.0002472049],"category_scores_gemma":[0.00003717837,0.00019427676,0.00007779591,0.00044359083,0.000053168165,0.000112245805,0.00004834718,0.00024922148,0.00007056734],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000034767316,0.00002485957,0.00004406132,0.00043861583,0.00015971417,0.0000665188,0.00070497394,0.010053649,0.9467074,0.0018322356,0.003016942,0.03691621],"study_design_scores_gemma":[0.00016434629,0.00010766168,0.00009434951,0.000055499935,0.000020949346,0.00003528002,0.000057661364,0.05327438,0.8321383,0.0010859045,0.11261586,0.00034981227],"about_ca_topic_score_codex":0.000014991396,"about_ca_topic_score_gemma":0.000027160215,"teacher_disagreement_score":0.11456916,"about_ca_system_score_codex":0.00023666391,"about_ca_system_score_gemma":0.00005207598,"threshold_uncertainty_score":0.79223764},"labels":[],"label_agreement":null},{"id":"W4391801166","doi":"10.1515/nanoph-2023-0796","title":"Electrically tunable plasmonic metasurface as a matrix of nanoantennas","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":6,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Huawei Technologies (Canada); McMaster University Medical Centre; McMaster University; Carleton University; University of Ottawa","funders":"","keywords":"Materials science; Plasmon; Optoelectronics; Metamaterial; Reflection (computer programming); Reflection coefficient; Capacitor; Indium tin oxide; Optics; Thin film; Nanotechnology; Voltage; Physics","score_opus":0.008803102265405274,"score_gpt":0.28579960109333935,"score_spread":0.2769964988279341,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4391801166","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.98308223,0.012632631,0.00039778414,0.00022497965,0.00089821854,0.00048331684,0.00010875075,0.00022931545,0.0019427645],"genre_scores_gemma":[0.9676139,0.002296453,0.024199868,0.00010470112,0.000025866357,0.00013343479,0.000016242151,0.0000652431,0.0055443165],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9978115,0.00009709294,0.00061849447,0.00053273194,0.00047126284,0.0004689189],"domain_scores_gemma":[0.9987843,0.00017653493,0.00015926037,0.00060385134,0.00014585207,0.00013021044],"candidate_categories":["insufficient_payload"],"consensus_categories":["insufficient_payload"],"category_scores_codex":[0.0010879335,0.00023081458,0.0004806137,0.0001000534,0.00011649022,0.00026524076,0.0006117791,0.00013513926,0.0022214146],"category_scores_gemma":[0.00013365858,0.00018897971,0.00017172674,0.00077000033,0.000088605244,0.00025443113,0.00014552026,0.00013213973,0.0019928403],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00003159596,0.000059923557,0.0000051424922,0.00014781795,0.000032621905,0.000011672187,0.00007858197,0.00018883386,0.98595953,0.01181181,0.0015040681,0.00016838916],"study_design_scores_gemma":[0.00014067194,0.000095879324,0.00001193622,0.00005142463,0.00009944962,0.00003186086,0.000013750012,0.0027619007,0.8476949,0.0017925933,0.14712967,0.00017599118],"about_ca_topic_score_codex":0.00020935,"about_ca_topic_score_gemma":0.000009755396,"teacher_disagreement_score":0.14562559,"about_ca_system_score_codex":0.00007356541,"about_ca_system_score_gemma":0.00048698825,"threshold_uncertainty_score":0.99878424},"labels":[],"label_agreement":null},{"id":"W4392511284","doi":"10.1515/nanoph-2023-0923","title":"Multifunctional all‐dielectric quarter‐wave plate metasurfaces for generating focused vector beams of Bell‐like states","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":14,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":true,"ca_institutions":"","funders":"Natural Science Foundation of Shandong Province; National Natural Science Foundation of China","keywords":"Quarter (Canadian coin); Dielectric; Optics; Physics; Telecommunications; Optoelectronics; Engineering; History","score_opus":0.031713257573598566,"score_gpt":0.2700833169395296,"score_spread":0.23837005936593103,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4392511284","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.98371243,0.004463228,0.007853161,0.00014736978,0.0019777145,0.0008568661,0.0007834462,0.00015545155,0.000050319988],"genre_scores_gemma":[0.6947535,0.0005163232,0.3028247,0.00016855139,0.00010949689,0.0005951335,0.00031052646,0.00009100077,0.00063073525],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9978406,0.00008340879,0.000700583,0.0005663625,0.00036697512,0.0004421036],"domain_scores_gemma":[0.99870193,0.0004106814,0.0002258573,0.00036516268,0.00019603859,0.000100338104],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.0011099387,0.00026142466,0.0004624603,0.000088014065,0.00021079436,0.00020251861,0.0002273925,0.00012614412,0.0004773604],"category_scores_gemma":[0.00006607982,0.00021707264,0.00017995985,0.00031330212,0.00006861632,0.00019402933,0.00004843004,0.00009594698,0.00009532634],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00005078781,0.00006110918,0.0000027456122,0.0001870175,0.00009048036,0.0000016676554,0.00043646005,0.0032813202,0.9930251,0.0010181001,0.0010714958,0.0007736792],"study_design_scores_gemma":[0.00033919467,0.00017958213,0.000013830004,0.000029076347,0.00014626041,0.0000050521653,0.000046345835,0.1639614,0.7807909,0.00051061873,0.05376512,0.0002126181],"about_ca_topic_score_codex":0.00010311462,"about_ca_topic_score_gemma":0.000028030368,"teacher_disagreement_score":0.29497156,"about_ca_system_score_codex":0.000062570376,"about_ca_system_score_gemma":0.00018031376,"threshold_uncertainty_score":0.88519657},"labels":[],"label_agreement":null},{"id":"W4392593845","doi":"10.1515/nanoph-2023-0819","title":"Optimization of a programmable <i>λ</i> /2‐pitch optical phased array","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Neural Networks and Reservoir Computing","field":"Computer Science","cited_by":19,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Toronto","funders":"Natural Sciences and Engineering Research Council of Canada; Max-Planck-Gesellschaft; CMC Microsystems","keywords":"Phased array; Phased-array optics; Computer science; Macrocell array; Computer architecture; Electronic engineering; Optoelectronics; Materials science; Optics; Physics; Telecommunications; Engineering; Logic gate; Logic synthesis","score_opus":0.009892281761152507,"score_gpt":0.241873261098863,"score_spread":0.2319809793377105,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4392593845","genre_codex":"methods","genre_gemma":"methods","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"methods","genre_consensus":"methods","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.01157144,0.0017189835,0.9818781,0.0005533368,0.00089680386,0.00023808965,0.000001074809,0.00032580836,0.0028163837],"genre_scores_gemma":[0.4891738,0.00010541661,0.5103533,0.000091400005,0.000059445505,0.000013870126,0.0000029380649,0.000017561497,0.00018224493],"study_design_codex":"simulation_or_modeling","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99877405,0.000027498136,0.00026475303,0.00035150826,0.00028284526,0.00029934323],"domain_scores_gemma":[0.99932444,0.00010140113,0.000049036626,0.00036341356,0.00008102881,0.00008068097],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00025199083,0.00012156229,0.00016615793,0.00005619747,0.00007018618,0.00024141539,0.0005376588,0.00008030303,0.000010947842],"category_scores_gemma":[0.000017032671,0.00009808505,0.00010142933,0.00083674537,0.000039268376,0.00024706806,0.00007493865,0.00017534327,0.000010552464],"study_design_candidate":"simulation_or_modeling","study_design_consensus":"simulation_or_modeling","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000028338358,0.00037496083,0.00005407631,0.00044283495,0.00009950502,0.00012540628,0.0006487927,0.6457021,0.2040683,0.055054642,0.001381717,0.09201928],"study_design_scores_gemma":[0.00014753774,0.00011167918,0.0000014857953,0.000098645614,0.0000070639003,0.000021087324,0.0000036611414,0.91701406,0.063811935,0.0004384737,0.018226411,0.00011795723],"about_ca_topic_score_codex":0.00000551059,"about_ca_topic_score_gemma":7.8912734e-7,"teacher_disagreement_score":0.47760236,"about_ca_system_score_codex":0.000027598768,"about_ca_system_score_gemma":0.00013318205,"threshold_uncertainty_score":0.39997923},"labels":[],"label_agreement":null},{"id":"W4394747813","doi":"10.1515/nanoph-2023-0900","title":"Engineering topological interface states in metal‐wire waveguides for broadband terahertz signal processing","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Terahertz technology and applications","field":"Engineering","cited_by":4,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut National de la Recherche Scientifique","funders":"Fonds de recherche du Québec – Nature et technologies; Natural Sciences and Engineering Research Council of Canada; Mitacs; Canada Research Chairs","keywords":"Terahertz radiation; SIGNAL (programming language); Broadband; Waveguide; Transmission (telecommunications); Signal processing; Interface (matter); Topology (electrical circuits); Computer science; Materials science; Optics; Optoelectronics; Electronic engineering; Telecommunications; Physics; Digital signal processing; Engineering; Electrical engineering; Computer hardware","score_opus":0.009899298134949863,"score_gpt":0.2493144367152465,"score_spread":0.23941513858029664,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4394747813","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9158349,0.012304253,0.06880512,0.0003165685,0.00023441599,0.00047894617,0.000037076254,0.0016247275,0.00036399195],"genre_scores_gemma":[0.98811287,0.00012293682,0.011231276,0.000022279271,0.000017576653,0.0002709744,0.0000122413685,0.000040281575,0.00016958828],"study_design_codex":"design_other","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.999188,0.0000044162675,0.00023334108,0.00023402284,0.000059256272,0.00028098057],"domain_scores_gemma":[0.99969435,0.000117172036,0.000010977844,0.00012594688,0.000018046469,0.00003353522],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00011457903,0.0001646963,0.00017417978,0.000101808524,0.000042711403,0.000068070265,0.00016278418,0.00018481282,0.000048966587],"category_scores_gemma":[0.000015829552,0.00015113619,0.000055414177,0.00027601497,0.000037363112,0.000119656055,0.000027217988,0.00026951302,0.000017014465],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000023094593,0.00010262321,0.00016559518,0.0011991721,0.00014639419,0.000047692018,0.00178271,0.05803129,0.44012526,0.0065775667,0.0014260521,0.49037254],"study_design_scores_gemma":[0.00012386218,0.000026838967,0.00003285341,0.00010320479,0.000012382906,0.000010109112,0.000057391233,0.72482854,0.09102954,0.0011817239,0.18242547,0.00016811414],"about_ca_topic_score_codex":0.0000042180714,"about_ca_topic_score_gemma":0.000012627126,"teacher_disagreement_score":0.6667972,"about_ca_system_score_codex":0.000093271025,"about_ca_system_score_gemma":0.000023169985,"threshold_uncertainty_score":0.61631554},"labels":[],"label_agreement":null},{"id":"W4396722964","doi":"10.1515/nanoph-2024-0044","title":"Reconfigurable quantum photonic circuits based on quantum dots","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Neural Networks and Reservoir Computing","field":"Computer Science","cited_by":2,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Vector Institute; Queen's University","funders":"Vector Institute; Natural Sciences and Engineering Research Council of Canada; Queen's University; Canada Foundation for Innovation","keywords":"Quantum dot; Photonics; Electronic circuit; Quantum; Nanomaterials; Photonic integrated circuit; Optoelectronics; Physics; Nanotechnology; Materials science; Quantum mechanics","score_opus":0.01939777314053513,"score_gpt":0.24832104122398777,"score_spread":0.22892326808345265,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4396722964","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.6522015,0.018712858,0.18655315,0.013062458,0.040652066,0.0029370675,0.00004701041,0.007658486,0.07817543],"genre_scores_gemma":[0.9955588,0.00017169202,0.0019075919,0.0014205066,0.00012207266,0.00003150586,0.0000059735007,0.000050820996,0.0007310089],"study_design_codex":"theoretical_or_conceptual","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9970613,0.00011009626,0.00042595644,0.0010058106,0.00058721896,0.0008096251],"domain_scores_gemma":[0.9980783,0.0004308097,0.00009035295,0.0011000517,0.00008545922,0.00021503805],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0006281689,0.0003460115,0.00032799432,0.00019744573,0.00030652378,0.00077781896,0.0013718653,0.00019176437,0.0000920132],"category_scores_gemma":[0.00004443168,0.0002874412,0.00024959948,0.0012276651,0.000047107304,0.00033573003,0.00013790576,0.00064686406,0.0004805882],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00007790216,0.00086722255,0.00014510492,0.0011213189,0.00023608054,0.0039106766,0.001052548,0.23199232,0.073161736,0.43172202,0.049805086,0.205908],"study_design_scores_gemma":[0.0002357569,0.00025029195,0.000028942824,0.00034560214,0.0000074085247,0.000035793964,0.0000050739427,0.9060907,0.008975527,0.003256374,0.08041651,0.00035203702],"about_ca_topic_score_codex":0.000034732064,"about_ca_topic_score_gemma":0.0000056490835,"teacher_disagreement_score":0.6740984,"about_ca_system_score_codex":0.00015132813,"about_ca_system_score_gemma":0.00041556923,"threshold_uncertainty_score":0.9999578},"labels":[],"label_agreement":null},{"id":"W4399172921","doi":"10.1515/nanoph-2024-0120","title":"Phase‐matched third‐harmonic generation in silicon nitride waveguides","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Advanced Fiber Laser Technologies","field":"Physics and Astronomy","cited_by":6,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Carleton University; University of Ottawa","funders":"Natural Sciences and Engineering Research Council of Canada; Canada Research Chairs; Canada First Research Excellence Fund; National Science Foundation","keywords":"Ultrashort pulse; Materials science; Optoelectronics; Silicon nitride; Second-harmonic generation; High harmonic generation; Silicon; Nonlinear optics; Optics; Nitride; Waveguide; Physics; Nanotechnology; Laser","score_opus":0.021222130293668335,"score_gpt":0.2941861233047556,"score_spread":0.27296399301108726,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4399172921","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99308735,0.0013656958,0.0020437276,0.00025139682,0.00028474125,0.00028053878,0.00004449256,0.00032058428,0.0023214857],"genre_scores_gemma":[0.99524814,0.000066844776,0.0037848656,0.00004645686,0.00008919949,0.000103500664,0.000090642774,0.000034215416,0.00053615356],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9988434,0.000019820445,0.00030778433,0.00037666337,0.00013995216,0.0003123962],"domain_scores_gemma":[0.99949265,0.000057686913,0.000048445116,0.0003320264,0.00003342215,0.000035788795],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00013643646,0.00019307976,0.00021374728,0.000119190976,0.000057459027,0.00009332272,0.00019531173,0.00010109988,0.00012808047],"category_scores_gemma":[0.000013534338,0.0001838425,0.00008838998,0.00043902206,0.00004770068,0.00024059007,0.00007046263,0.000343735,0.00013489819],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00002283307,0.0003812598,0.00064814364,0.000052443742,0.0000827848,0.00004332964,0.0005538928,0.00087051577,0.88420784,0.03937922,0.0029059001,0.07085181],"study_design_scores_gemma":[0.00086259097,0.00008027324,0.000017391663,0.00004676606,0.00001959874,0.0000015847627,0.0002512673,0.09045565,0.8674862,0.018669343,0.021838846,0.00027050384],"about_ca_topic_score_codex":0.000074777185,"about_ca_topic_score_gemma":0.000019733816,"teacher_disagreement_score":0.08958513,"about_ca_system_score_codex":0.00010821979,"about_ca_system_score_gemma":0.00011661163,"threshold_uncertainty_score":0.7496879},"labels":[],"label_agreement":null},{"id":"W4400219447","doi":"10.1515/nanoph-2024-0269","title":"Inverse design of color routers in CMOS image sensors: toward minimizing interpixel crosstalk","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"CCD and CMOS Imaging Sensors","field":"Engineering","cited_by":20,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Artificial Intelligence in Medicine (Canada)","funders":"Institute for Information and Communications Technology Promotion; Korea Semiconductor Research Consortium; Ministry of Culture, Sports and Tourism; Ministry of Science and ICT, South Korea; Ministry of Trade, Industry and Energy","keywords":"Pixel; Miniaturization; Computer science; Router; Crosstalk; Artificial intelligence; Optoelectronics; Optics; Materials science; Physics; Nanotechnology; Computer network","score_opus":0.015122505728628595,"score_gpt":0.23626941429325082,"score_spread":0.22114690856462224,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4400219447","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.99313873,0.0007933284,0.0031921118,0.000089926725,0.0009903344,0.00029452564,0.000034422894,0.000427074,0.0010395201],"genre_scores_gemma":[0.97628236,0.00022018705,0.023108918,0.00005520223,0.000022864042,0.000019729632,0.0000050281556,0.0000768299,0.00020886323],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9988303,0.000033030596,0.00037137218,0.0002528635,0.00016596838,0.0003464381],"domain_scores_gemma":[0.9995019,0.00014224676,0.000025996535,0.00023157487,0.000033057262,0.000065249325],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00021588885,0.00021712552,0.00028371354,0.0001818149,0.000019293175,0.00009748608,0.0001730732,0.00011384298,0.000047832033],"category_scores_gemma":[0.000052554853,0.00022612691,0.00010281294,0.0004301795,0.00008911323,0.00020506725,0.00004531603,0.00027636785,0.00006906505],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000081980535,0.000060760118,0.00013945594,0.0009844616,0.00012479004,0.00057827035,0.012790076,0.11938399,0.8581924,0.00012530346,0.005150226,0.0023882731],"study_design_scores_gemma":[0.00038719657,0.000044025935,0.000044538865,0.00035074409,0.000023174389,0.000026902277,0.0007984095,0.8621114,0.13017653,0.00006220762,0.0057044756,0.00027038762],"about_ca_topic_score_codex":0.000048723265,"about_ca_topic_score_gemma":0.000014866402,"teacher_disagreement_score":0.7427274,"about_ca_system_score_codex":0.00020409933,"about_ca_system_score_gemma":0.000068293826,"threshold_uncertainty_score":0.9221188},"labels":[],"label_agreement":null},{"id":"W4401970841","doi":"10.1515/nanoph-2024-0222","title":"Molecular surface coverage standards by reference‐free GIXRF supporting SERS and SEIRA substrate benchmarking","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Surface and Thin Film Phenomena","field":"Physics and Astronomy","cited_by":6,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Natural Sciences and Engineering Research Council of Canada","funders":"HORIZON EUROPE Framework Programme; European Commission; European Association of National Metrology Institutes","keywords":"Materials science; Nanotechnology; Raman spectroscopy; Benchmarking; Surface modification; Substrate (aquarium); Optics; Chemical engineering; Physics","score_opus":0.007045375018194803,"score_gpt":0.25365516415205686,"score_spread":0.24660978913386206,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4401970841","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9677535,0.0020870382,0.0006458598,0.000102162594,0.0003521779,0.00019946841,0.0009348182,0.00009496376,0.02782999],"genre_scores_gemma":[0.9983468,0.000092510825,0.0006554755,0.000081466365,0.00003315396,0.000008686572,0.00016063853,0.000049160757,0.0005721069],"study_design_codex":"bench_or_experimental","study_design_gemma":"not_applicable","domain_scores_codex":[0.9982565,0.000044762317,0.00031998887,0.0004960218,0.00039812175,0.00048457913],"domain_scores_gemma":[0.9992462,0.000073272575,0.00009109498,0.00036822498,0.0000794867,0.0001417549],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00053022633,0.0002744566,0.00026673736,0.00003125404,0.00015856134,0.0003504297,0.00021713269,0.0000864721,0.00063147204],"category_scores_gemma":[0.000007733001,0.0002699711,0.00008616651,0.00023953301,0.000057041754,0.0002277151,0.00013207685,0.0003768059,0.00001811208],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00027624855,0.00047999178,0.072933115,0.001258275,0.002521207,0.0006191405,0.009561914,0.008080031,0.5986527,0.17145067,0.050267268,0.083899416],"study_design_scores_gemma":[0.0030234861,0.0005245531,0.00046744265,0.00061288825,0.00036278524,0.000016177957,0.0025192,0.051416468,0.2876003,0.04198844,0.6088202,0.0026480507],"about_ca_topic_score_codex":0.00024018362,"about_ca_topic_score_gemma":0.0000059261865,"teacher_disagreement_score":0.5585529,"about_ca_system_score_codex":0.00008251915,"about_ca_system_score_gemma":0.0003213533,"threshold_uncertainty_score":0.99997526},"labels":[],"label_agreement":null},{"id":"W4403866826","doi":"10.1515/nanoph-2024-0471","title":"Large‐scale high purity and brightness structural color generation in layered thin film structures via coupled cavity resonance","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic Crystals and Applications","field":"Physics and Astronomy","cited_by":8,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"National Natural Science Foundation of China; College of Family Physicians of Canada; Wuhan National Laboratory for Optoelectronics; National Science Foundation","keywords":"Brightness; Materials science; Nanomaterials; Resonance (particle physics); Thin film; Structural coloration; Nanoscopic scale; Nanotechnology; Optoelectronics; Optics; Physics; Photonic crystal","score_opus":0.0072803578874966945,"score_gpt":0.24927626301801767,"score_spread":0.24199590513052097,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4403866826","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9966491,0.001043335,0.00077429716,0.00014306544,0.0002509026,0.00045740904,0.00047970872,0.0000497135,0.00015245735],"genre_scores_gemma":[0.9981225,0.00002970833,0.0010736687,0.000044907094,0.000112583686,0.00011333107,0.0002835506,0.000022606495,0.00019714965],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99874336,0.00003732845,0.0002778211,0.000461374,0.00017056424,0.00030955963],"domain_scores_gemma":[0.99948955,0.000046712434,0.00006070064,0.00027784263,0.00004673983,0.00007845004],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00016101889,0.00020107966,0.00024639547,0.000040541276,0.00021427921,0.00016512738,0.00014541335,0.00009952217,0.00036306298],"category_scores_gemma":[0.0000031189556,0.00017987011,0.000058747246,0.000265673,0.000059599337,0.00016529129,0.000078349934,0.00028510104,0.000006187951],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00016662049,0.00043388054,0.014667382,0.000304856,0.00019254112,0.000053007017,0.008847855,0.013281238,0.6076069,0.3429921,0.003365438,0.0080881845],"study_design_scores_gemma":[0.0007124282,0.000024705507,0.012761242,0.00002301398,0.00002176467,0.0000049988043,0.00016411301,0.9226237,0.026772328,0.024342408,0.012246186,0.00030313004],"about_ca_topic_score_codex":0.001189757,"about_ca_topic_score_gemma":0.0012027874,"teacher_disagreement_score":0.90934247,"about_ca_system_score_codex":0.00006911349,"about_ca_system_score_gemma":0.00012358463,"threshold_uncertainty_score":0.733489},"labels":[],"label_agreement":null},{"id":"W4404697825","doi":"10.1515/nanoph-2024-0500","title":"Design and fabrication of robust hybrid photonic crystal cavities","year":2024,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic Crystals and Applications","field":"Physics and Astronomy","cited_by":4,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Natural Sciences and Engineering Research Council of Canada; Materials Research Science and Engineering Center, Harvard University; Division of Materials Research; Office of Science; Princeton University; Gordon and Betty Moore Foundation; U.S. Department of Energy; Princeton Center for Complex Materials; National Science Foundation","keywords":"Photonic crystal; Fabrication; Materials science; Optoelectronics; Diamond; Photonics; Refractive index; Substrate (aquarium); Optics; Nanotechnology; Physics","score_opus":0.0150501998846381,"score_gpt":0.23857958355115438,"score_spread":0.22352938366651628,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4404697825","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.87475747,0.0022499321,0.11723204,0.0001010853,0.00020051585,0.00067345425,0.00027135588,0.000101915,0.004412201],"genre_scores_gemma":[0.9933755,0.00009287585,0.0057929736,0.000014257761,0.00003451741,0.00012681476,0.000056168115,0.000025527173,0.00048140704],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99911964,0.000023495546,0.00024638366,0.0002810227,0.00013421259,0.00019524447],"domain_scores_gemma":[0.9994363,0.00011794193,0.00006808078,0.0002525091,0.00006351006,0.00006163223],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00017016585,0.00014455595,0.00018121571,0.000052962307,0.000088772926,0.000076305805,0.000121489466,0.00003112709,0.00033531216],"category_scores_gemma":[0.0000031154993,0.0001378759,0.00007320455,0.0001923682,0.00009156611,0.000116246,0.00005112218,0.00012724224,0.000012768074],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000044616732,0.0003517051,0.00062152813,0.00033239217,0.0003191538,0.000007809581,0.0018422862,0.0051542413,0.87183076,0.09559472,0.0056016454,0.018299147],"study_design_scores_gemma":[0.0005964798,0.00014248981,0.00021461812,0.00018336292,0.00017304394,0.00001923534,0.0007449048,0.41317895,0.48936507,0.02251862,0.072276525,0.0005866921],"about_ca_topic_score_codex":0.0001653977,"about_ca_topic_score_gemma":0.0000016073309,"teacher_disagreement_score":0.4080247,"about_ca_system_score_codex":0.000030873336,"about_ca_system_score_gemma":0.00017699729,"threshold_uncertainty_score":0.5622416},"labels":[],"label_agreement":null},{"id":"W4404701061","doi":"10.1515/nanoph-2024-0621","title":"Corrigendum to: modeling with graded interfaces: tool for understanding and designing record‐high power and efficiency mid‐infrared quantum cascade lasers","year":2024,"lang":"en","type":"erratum","venue":"Nanophotonics","topic":"Spectroscopy and Laser Applications","field":"Chemistry","cited_by":0,"is_retracted":false,"has_abstract":false,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Nexen (Canada)","funders":"","keywords":"Cascade; Quantum; Infrared; Quantum cascade laser; Laser; Nanomaterials; Power (physics); Optoelectronics; Materials science; Computer science; Nanotechnology; Optics; Physics; Engineering; Quantum mechanics; Chemical engineering","score_opus":0.03172256671504084,"score_gpt":0.2650923673177031,"score_spread":0.23336980060266224,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4404701061","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.5774133,0.016660593,0.33826333,0.00081782276,0.027818454,0.0053446786,0.0022703868,0.0016183399,0.029793067],"genre_scores_gemma":[0.85818404,0.0022769636,0.021627871,0.0004516076,0.00048168903,0.0015155857,0.0008949639,0.0007458164,0.113821454],"study_design_codex":"not_applicable","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.99735415,0.000015878122,0.0004965416,0.0011469086,0.0003284796,0.00065803836],"domain_scores_gemma":[0.9988291,0.00014287623,0.0001860997,0.0005361425,0.00008826496,0.00021747021],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00020988857,0.0006087909,0.00061554497,0.00017249634,0.00042491968,0.00035902616,0.0003206214,0.00071663194,0.00008736464],"category_scores_gemma":[0.00007207975,0.0005636426,0.00009927826,0.0003505129,0.00011026365,0.00010158138,0.00014203461,0.001075124,0.000007365964],"study_design_candidate":"not_applicable","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0025489505,0.0004928642,0.00007372162,0.010899415,0.001999142,0.00021769377,0.019133208,0.0040913397,0.33092514,0.022914404,0.6063325,0.0003716514],"study_design_scores_gemma":[0.0030906636,0.0011800987,0.0000016862781,0.006678026,0.0016223986,0.00016348893,0.015245196,0.69480276,0.11601489,0.023108143,0.13418855,0.0039041303],"about_ca_topic_score_codex":0.000106107895,"about_ca_topic_score_gemma":0.00011644571,"teacher_disagreement_score":0.6907114,"about_ca_system_score_codex":0.0005669733,"about_ca_system_score_gemma":0.0004499708,"threshold_uncertainty_score":0.99968153},"labels":[],"label_agreement":null},{"id":"W4406852024","doi":"10.1515/nanoph-2024-0610","title":"Photocurrent‐induced harmonics in nanostructures","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Laser-Matter Interactions and Applications","field":"Physics and Astronomy","cited_by":3,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Innovation Cluster (Canada)","funders":"Deutsche Forschungsgemeinschaft","keywords":"Photocurrent; Harmonics; Electron; Ionization; Nanostructure; Physics; Ion; Materials science; Optoelectronics; Nanotechnology; Quantum mechanics","score_opus":0.007941247667171993,"score_gpt":0.29328138998569303,"score_spread":0.28534014231852106,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4406852024","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9704464,0.000041083487,0.00037278884,0.00042972446,0.00051047374,0.0003813948,0.000055804765,0.000034017914,0.027728332],"genre_scores_gemma":[0.9975285,0.000004290674,0.0006113747,0.00025662425,0.000023657294,0.00021389783,0.00003516634,0.000010527038,0.0013159825],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99919546,0.000017597895,0.00024533857,0.00024339482,0.000080880825,0.00021732692],"domain_scores_gemma":[0.9994843,0.0000443728,0.000060982395,0.0003276784,0.000045949073,0.000036687143],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00005017352,0.00013388129,0.00014971869,0.00008789109,0.00010644888,0.00006381115,0.00021229779,0.00004596876,0.0007184285],"category_scores_gemma":[0.0000037926052,0.00012811403,0.0000805246,0.00040529532,0.000018719535,0.000080183614,0.00006336764,0.00023348354,0.0000809319],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00010269273,0.002257819,0.09633599,0.000116566196,0.0003712607,0.0000093679755,0.0012186145,0.0007500633,0.5406876,0.20333488,0.058486085,0.09632903],"study_design_scores_gemma":[0.001536245,0.000030418192,0.008993689,0.00012880187,0.000045772038,0.0000012584651,0.0005124991,0.0054210764,0.5247443,0.027870765,0.43025208,0.00046312332],"about_ca_topic_score_codex":0.00030494848,"about_ca_topic_score_gemma":0.00004829655,"teacher_disagreement_score":0.371766,"about_ca_system_score_codex":0.00005287319,"about_ca_system_score_gemma":0.0001252638,"threshold_uncertainty_score":0.78662884},"labels":[],"label_agreement":null},{"id":"W4406906276","doi":"10.1515/nanoph-2024-0567","title":"Ultrafast pulse propagation time‐domain dynamics in dispersive one‐dimensional photonic waveguides","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photonic and Optical Devices","field":"Engineering","cited_by":1,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Natural Sciences and Engineering Research Council of Canada; Türkiye Bilimsel ve Teknolojik Araştırma Kurumu","keywords":"Ultrashort pulse; Photonics; Time domain; Materials science; Pulse (music); Optics; Temporal resolution; Pulse duration; Impulse response; Grating; Optoelectronics; Physics; Electronic engineering; Computer science; Engineering; Mathematics","score_opus":0.004389096789651183,"score_gpt":0.20338193696221438,"score_spread":0.1989928401725632,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4406906276","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9295792,0.00046268798,0.0002317305,0.00022710401,0.00036479975,0.0005649561,0.00004949203,0.00022463902,0.06829538],"genre_scores_gemma":[0.9959363,0.00017130932,0.00259147,0.00022450379,0.000012199229,0.00007690969,0.00010302943,0.00003995995,0.00084433105],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9983747,0.0000373335,0.00045348817,0.000354727,0.0002806646,0.000499061],"domain_scores_gemma":[0.99930614,0.00014431674,0.0000420608,0.00033537202,0.00007391272,0.00009820796],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.0002581472,0.00027789958,0.00036089026,0.00018507655,0.000083494895,0.0000498049,0.0002673554,0.00024268487,0.00020807883],"category_scores_gemma":[0.00006232763,0.00028559036,0.00010373789,0.0006600515,0.00009352553,0.00017799347,0.00006493724,0.00038309023,0.00018352475],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00049676705,0.0014010993,0.003218366,0.001683587,0.00078930176,0.0002650022,0.0015915668,0.12089452,0.6836779,0.17614293,0.0010034273,0.008835512],"study_design_scores_gemma":[0.0007734534,0.000040082145,0.0012033024,0.00023947355,0.00003076423,0.00000595338,0.0001372805,0.9375704,0.055675507,0.0027701384,0.0012151182,0.00033850886],"about_ca_topic_score_codex":0.00004975576,"about_ca_topic_score_gemma":0.00039022835,"teacher_disagreement_score":0.8166759,"about_ca_system_score_codex":0.0010195555,"about_ca_system_score_gemma":0.00016357261,"threshold_uncertainty_score":0.99995965},"labels":[],"label_agreement":null},{"id":"W4406977510","doi":"10.1515/nanoph-2024-0616","title":"Space‐time couplings in ultrashort lasers with arbitrary nonparaxial focusing","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Orbital Angular Momentum in Optics","field":"Physics and Astronomy","cited_by":4,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Waterloo; Institut National de la Recherche Scientifique","funders":"Natural Sciences and Engineering Research Council of Canada; Fonds De La Recherche Scientifique - FNRS; Alliance de recherche numérique du Canada; European Commission","keywords":"Physics; Optics; Laser; Chirp; Diffraction; Space time; Curvature; Focus (optics); Mathematics; Geometry","score_opus":0.001853368568125025,"score_gpt":0.2028373432081457,"score_spread":0.20098397464002069,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4406977510","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.94892275,0.00006694254,0.00035356288,0.00026339435,0.00016396916,0.00030218574,0.000020498166,0.000041242572,0.04986542],"genre_scores_gemma":[0.99111724,0.000004707008,0.0054878164,0.00016018859,0.00005075963,0.000031902546,0.000036044006,0.00003076496,0.0030805715],"study_design_codex":"observational","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99889183,0.000012074783,0.00023188515,0.0003096512,0.0001874733,0.00036710294],"domain_scores_gemma":[0.999492,0.000056864563,0.000066778055,0.00027709026,0.00004593148,0.000061322964],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.000118757496,0.000209928,0.00025753124,0.0000963127,0.00008233157,0.00006639988,0.00017887267,0.0000681333,0.00018091704],"category_scores_gemma":[0.0000042093825,0.00019681611,0.00007436814,0.0004535393,0.000079846315,0.00012361014,0.000059367474,0.00028579117,0.00006143746],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0011272392,0.0034971978,0.57437724,0.00036318813,0.0011891093,0.0003390234,0.003752107,0.010785603,0.25540337,0.1381879,0.0042307978,0.0067472532],"study_design_scores_gemma":[0.011248545,0.00082499086,0.013256759,0.0014432259,0.0004712879,0.000015391897,0.0021394934,0.085674495,0.7604585,0.024711462,0.096491486,0.0032643373],"about_ca_topic_score_codex":0.00018460443,"about_ca_topic_score_gemma":0.000014770482,"teacher_disagreement_score":0.56112045,"about_ca_system_score_codex":0.000087687346,"about_ca_system_score_gemma":0.00024620828,"threshold_uncertainty_score":0.8025928},"labels":[],"label_agreement":null},{"id":"W4407230296","doi":"10.1515/nanoph-2024-0515","title":"Freeform thin‐film lithium niobate mode converter for photon‐pair generation","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photorefractive and Nonlinear Optics","field":"Physics and Astronomy","cited_by":8,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Artificial Intelligence in Medicine (Canada)","funders":"National Research Council of Science and Technology; Korea Creative Content Agency; National Research Foundation of Korea; Korea Institute of Science and Technology","keywords":"Lithium niobate; Materials science; Nanomaterials; Photon; Optoelectronics; Mode (computer interface); Thin film; Lithium (medication); Optics; Nanotechnology; Computer science; Physics; Psychology","score_opus":0.013827012114064178,"score_gpt":0.28213904614127594,"score_spread":0.26831203402721177,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4407230296","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.93447375,0.00013165486,0.027210753,0.00030061402,0.0021990582,0.0012399461,0.00073970767,0.00010069614,0.03360379],"genre_scores_gemma":[0.9706165,0.000022996166,0.012882555,0.001243226,0.00052811496,0.00034557693,0.00064556225,0.000049532206,0.013665928],"study_design_codex":"bench_or_experimental","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9988314,0.00002316309,0.00030097066,0.0003505676,0.00014532972,0.00034856555],"domain_scores_gemma":[0.9990628,0.00007576485,0.00011453586,0.00039377366,0.00028099012,0.00007213823],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00016695936,0.000231743,0.0002712092,0.00006254926,0.00022136832,0.000079607926,0.00021728817,0.0001198594,0.00015503835],"category_scores_gemma":[0.000020703055,0.00021269722,0.00019700499,0.00017468976,0.000044488348,0.0001460042,0.00006367116,0.00020617667,0.000044196902],"study_design_candidate":"bench_or_experimental","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00085147173,0.0022498101,0.01653238,0.00035381177,0.0017573821,0.000006600034,0.0022710168,0.0020986681,0.5589876,0.15405308,0.24821895,0.012619202],"study_design_scores_gemma":[0.0007746112,0.00005190771,0.000029289857,0.00001737342,0.000048424634,1.4040779e-7,0.00008009972,0.44477233,0.33699423,0.0037495135,0.2133045,0.00017756847],"about_ca_topic_score_codex":0.00025931606,"about_ca_topic_score_gemma":0.000036631667,"teacher_disagreement_score":0.44267365,"about_ca_system_score_codex":0.00008410194,"about_ca_system_score_gemma":0.00028945954,"threshold_uncertainty_score":0.8673541},"labels":[],"label_agreement":null},{"id":"W4408919619","doi":"10.1515/nanoph-2024-0712","title":"From signal processing of telecommunication signals to high pulse energy lasers: the Mamyshev regenerator case","year":2025,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Advanced Fiber Laser Technologies","field":"Physics and Astronomy","cited_by":8,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"McGill University","funders":"Natural Sciences and Engineering Research Council of Canada; Conseil régional de Bourgogne-Franche-Comté; Agence Nationale de la Recherche","keywords":"Laser; Regenerative heat exchanger; SIGNAL (programming language); Pulse (music); Signal processing; Telecommunications; Energy (signal processing); Materials processing; Optoelectronics; Materials science; Optics; Electronic engineering; Computer science; Physics; Engineering","score_opus":0.018918964120681735,"score_gpt":0.30140009329734685,"score_spread":0.2824811291766651,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4408919619","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.00024207731,0.9921686,0.005149211,0.000069158355,0.00010133602,0.0007432435,0.0010506429,0.00009659867,0.00037914785],"genre_scores_gemma":[0.0069747292,0.9652684,0.02456463,0.00009797903,0.00018009043,0.001201501,0.0007971226,0.00011823336,0.00079734484],"study_design_codex":"design_other","study_design_gemma":"not_applicable","domain_scores_codex":[0.9979205,0.00017938556,0.0008074987,0.0005422618,0.0002102822,0.0003400421],"domain_scores_gemma":[0.99705786,0.0005232875,0.0007152514,0.0014533744,0.00018649558,0.00006374287],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00016645227,0.0005017534,0.0012787352,0.00015133223,0.00022599261,0.0000781951,0.0012029156,0.0003053423,0.00014829122],"category_scores_gemma":[0.000025165275,0.00036701496,0.0003364928,0.00095171545,0.0001034936,0.00010665763,0.0005370347,0.0005261078,0.0000115921175],"study_design_candidate":"design_other","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000005223814,0.00006888211,6.7043896e-7,0.00084195426,0.00014599544,0.000017091184,0.000054540036,0.00014572588,0.00007354524,0.0014102801,0.00044349564,0.9967926],"study_design_scores_gemma":[0.00016962289,0.00004777533,6.03934e-8,0.006182014,0.0006437304,0.000008771349,0.0002597286,0.00016827678,0.009930135,0.0031278327,0.9789736,0.0004884288],"about_ca_topic_score_codex":0.0009038789,"about_ca_topic_score_gemma":0.00005077578,"teacher_disagreement_score":0.99630415,"about_ca_system_score_codex":0.00012257168,"about_ca_system_score_gemma":0.0007187514,"threshold_uncertainty_score":0.99987817},"labels":[],"label_agreement":null},{"id":"W4409168734","doi":"10.1515/nanoph-2024-0719","title":"Generation of fast photoelectrons in strong‐field emission from metal nanoparticles","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Laser-Matter Interactions and Applications","field":"Physics and Astronomy","cited_by":1,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut National de la Recherche Scientifique","funders":"Air Force Office of Scientific Research; National Science Foundation","keywords":"Photoelectric effect; Nanomaterials; Nanoparticle; Materials science; Metal; Field (mathematics); Field electron emission; Nanotechnology; Optoelectronics; Physics; Electron; Metallurgy; Quantum mechanics","score_opus":0.01662128975498912,"score_gpt":0.2864179484747989,"score_spread":0.2697966587198098,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4409168734","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9923113,0.000043993386,0.0022971672,0.00025991778,0.00011548982,0.00016578706,0.00006494736,0.000012171869,0.0047292467],"genre_scores_gemma":[0.99819005,0.0000038224966,0.0009371819,0.00007317268,0.000027938238,0.000081027014,0.00007526224,0.0000067752985,0.00060476153],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99930865,0.000022038324,0.00026474913,0.00018604627,0.0000756033,0.00014292054],"domain_scores_gemma":[0.9995603,0.00006042415,0.00007653525,0.00023334668,0.000042268923,0.000027107266],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.000046645313,0.00009705021,0.00015131172,0.000055328466,0.0000653649,0.00002453263,0.00011537884,0.000037794205,0.00058453815],"category_scores_gemma":[0.000004273357,0.00008908549,0.00006882008,0.00024000114,0.000015719,0.00008985569,0.000036724465,0.00012267506,0.000014117734],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000010375735,0.00023444027,0.004653086,0.0000029639455,0.00003424742,1.6269843e-7,0.00008606841,0.00013848119,0.98415107,0.005538769,0.0011774075,0.003972936],"study_design_scores_gemma":[0.00030733508,0.000022593294,0.0004603528,0.000026385496,0.000025968522,6.931086e-8,0.00018053922,0.011169121,0.9809266,0.0013979701,0.0054074293,0.00007567412],"about_ca_topic_score_codex":0.0012859583,"about_ca_topic_score_gemma":0.00012252267,"teacher_disagreement_score":0.011030639,"about_ca_system_score_codex":0.000030372341,"about_ca_system_score_gemma":0.00008704421,"threshold_uncertainty_score":0.6400283},"labels":[],"label_agreement":null},{"id":"W4410035613","doi":"10.1515/nanoph-2024-0704","title":"Active metasurface designs for lensless and detector‐limited imaging","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Metamaterials and Metasurfaces Applications","field":"Materials Science","cited_by":3,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Air Force Office of Scientific Research; Natural Sciences and Engineering Research Council of Canada; Meta","keywords":"Detector; Optics; Physics; Scalability; Image sensor; Pixel; Computer science; Amplitude; Plasmon","score_opus":0.02682591208044422,"score_gpt":0.29352207254722573,"score_spread":0.2666961604667815,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4410035613","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9845544,0.0013895958,0.011665338,0.00030756608,0.00055767683,0.0008709938,0.00018166935,0.000094143776,0.00037860306],"genre_scores_gemma":[0.9177815,0.00017132032,0.08081115,0.0003786152,0.000013708639,0.0003807849,0.000015363717,0.000025822199,0.00042176782],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9987812,0.00007643953,0.00028130977,0.0004249653,0.00012392522,0.0003121335],"domain_scores_gemma":[0.9990263,0.00025441777,0.00012714068,0.00036665317,0.00015717703,0.00006831311],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00064758665,0.00017285431,0.0003152678,0.00005534539,0.00030661657,0.00013843385,0.00021956446,0.000067078465,0.000084747306],"category_scores_gemma":[0.00014902909,0.00015505655,0.000060186198,0.00020554573,0.00008832741,0.00013400672,0.000085892505,0.00005563618,0.000021741362],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00005804616,0.000025175923,0.000031903935,0.000050408675,0.000017042541,4.040255e-7,0.00008543244,0.000040979758,0.995249,0.0020120118,0.0002449292,0.002184711],"study_design_scores_gemma":[0.00049679575,0.000018467787,0.00026655814,0.000019078443,0.00011121422,0.000002089527,0.000092177994,0.0029067758,0.954212,0.0014185916,0.040302094,0.0001541488],"about_ca_topic_score_codex":0.000052869196,"about_ca_topic_score_gemma":0.000016933227,"teacher_disagreement_score":0.06914581,"about_ca_system_score_codex":0.000048779388,"about_ca_system_score_gemma":0.00009466418,"threshold_uncertainty_score":0.6323023},"labels":[],"label_agreement":null},{"id":"W4410757843","doi":"10.1515/nanoph-2025-0034","title":"Tutorial: Hong–Ou–Mandel interference with structured photons","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Quantum Information and Cryptography","field":"Computer Science","cited_by":2,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Ottawa","funders":"H2020 European Research Council; Canada Research Chairs","keywords":"Photon; Interference (communication); Nanomaterials; Physics; Optoelectronics; Computer science; Nanotechnology; Materials science; Optics; Telecommunications","score_opus":0.0061218783503337705,"score_gpt":0.22933066989723677,"score_spread":0.223208791546903,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4410757843","genre_codex":"methods","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":null,"domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.16012545,0.0003889827,0.7506489,0.0012892605,0.0046528527,0.0007513376,0.000018257784,0.0009979961,0.08112693],"genre_scores_gemma":[0.95725024,0.00007081342,0.039791897,0.0024274408,0.000016920585,0.00003986837,0.0000060850825,0.00000882077,0.00038794233],"study_design_codex":"theoretical_or_conceptual","study_design_gemma":"not_applicable","domain_scores_codex":[0.9988225,0.00002782313,0.00027882674,0.00030922555,0.00027066207,0.00029094328],"domain_scores_gemma":[0.9988506,0.000043721982,0.00010628835,0.00075142545,0.00016426762,0.000083686835],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00014168891,0.00018746499,0.0001902523,0.00019593595,0.00016198333,0.0002837104,0.0010326277,0.00010409923,0.000038241586],"category_scores_gemma":[0.000020788772,0.00014748178,0.00007813298,0.0011465211,0.000076683275,0.0004832154,0.00017963961,0.0002153811,0.000034005185],"study_design_candidate":"theoretical_or_conceptual","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00014474292,0.00013152786,0.0012475171,0.00010149926,0.00015082634,0.000020530153,0.0019226734,0.00022938607,0.010611394,0.9481428,0.01321628,0.024080815],"study_design_scores_gemma":[0.004759039,0.00064009556,0.00472941,0.00031933078,0.00006156427,0.00004942439,0.0002562218,0.24253993,0.14547478,0.04742898,0.55246025,0.0012809467],"about_ca_topic_score_codex":0.000016666098,"about_ca_topic_score_gemma":0.00003732016,"teacher_disagreement_score":0.9007138,"about_ca_system_score_codex":0.000039413488,"about_ca_system_score_gemma":0.00028214045,"threshold_uncertainty_score":0.60141325},"labels":[],"label_agreement":null},{"id":"W4411890027","doi":"10.1515/nanoph-2025-0159","title":"Design strategies, manufacturing, and applications of radiative cooling technologies","year":2025,"lang":"en","type":"review","venue":"Nanophotonics","topic":"Thermal Radiation and Cooling Technologies","field":"Engineering","cited_by":3,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Artificial Intelligence in Medicine (Canada)","funders":"Directorate for Engineering; Korea Creative Content Agency; National Research Foundation of Korea","keywords":"Radiative cooling; Emissivity; Materials science; Efficient energy use; Metamaterial; Passive cooling; Smart material; Material efficiency; Mechanical engineering; Nanotechnology; Computer science; Systems engineering; Process engineering; Architectural engineering; Thermal; Engineering; Optoelectronics","score_opus":0.017187208668848188,"score_gpt":0.26640478340472507,"score_spread":0.24921757473587688,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4411890027","genre_codex":"review","genre_gemma":"review","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"review","genre_consensus":"review","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.0000021441863,0.9727368,0.023983445,0.0000021890178,0.0000820592,0.0008900271,0.000056231132,0.0015471372,0.00069997844],"genre_scores_gemma":[0.00015797085,0.99304676,0.0061691706,0.0000020414434,0.000005827336,0.00050548976,0.000016932521,0.00003631382,0.000059468442],"study_design_codex":"design_other","study_design_gemma":"not_applicable","domain_scores_codex":[0.9990236,0.00002409166,0.00041524318,0.00023831164,0.00009159123,0.00020712453],"domain_scores_gemma":[0.9990681,0.00028154845,0.0001588807,0.0004457547,0.000026414733,0.000019300498],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00010470371,0.00032392293,0.0008730512,0.00031552734,0.000054677355,0.000041168983,0.00043989063,0.0005940484,0.0000060946563],"category_scores_gemma":[0.000036596048,0.00029819878,0.00010814927,0.00037021784,0.00010739567,0.00005903712,0.00009794951,0.0004273536,0.000006210452],"study_design_candidate":"not_applicable","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.0000011675655,0.0000067496935,2.968121e-8,0.0096567925,0.00010335157,0.0000012006246,0.000023298297,0.0033638068,0.0000029352113,0.0020219765,0.00009783171,0.9847209],"study_design_scores_gemma":[0.00006898455,0.000019691879,1.6176952e-7,0.0025708703,0.00022389975,0.000005755191,0.00018938484,0.0023072641,0.00164198,0.0014205923,0.9912318,0.00031959024],"about_ca_topic_score_codex":0.0000025010136,"about_ca_topic_score_gemma":0.0000012855483,"teacher_disagreement_score":0.991134,"about_ca_system_score_codex":0.00010118058,"about_ca_system_score_gemma":0.00021928435,"threshold_uncertainty_score":0.999947},"labels":[],"label_agreement":null},{"id":"W4415261143","doi":"10.1515/nanoph-2025-0394","title":"Beyond limits: a tribute to Dai‐Sik Kim’s academic legacy and vision","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":1,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"University of Toronto","funders":"","keywords":"Tribute; Passion; Terahertz radiation; Plasmon","score_opus":0.00996994895087414,"score_gpt":0.29084922278037345,"score_spread":0.2808792738294993,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4415261143","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.983894,0.0035695736,0.00055835303,0.0016235098,0.000521679,0.0004035712,0.000046116587,0.00025622122,0.009126971],"genre_scores_gemma":[0.9708903,0.005755836,0.0114754,0.0008733573,0.000012063595,0.000099479366,0.000027469598,0.00006787307,0.010798226],"study_design_codex":"bench_or_experimental","study_design_gemma":"not_applicable","domain_scores_codex":[0.9985924,0.000025781026,0.00027680266,0.00031308885,0.00027528108,0.0005166521],"domain_scores_gemma":[0.99921566,0.00019911841,0.000015897269,0.00030489365,0.00005519212,0.0002092404],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00034678046,0.00020731613,0.0002770713,0.00018371553,0.00012461204,0.000098574805,0.00029290115,0.00028560127,0.00003354434],"category_scores_gemma":[0.0001401591,0.00020591622,0.000049013208,0.0006136248,0.000039464747,0.00021538629,0.00013770752,0.0006420867,0.0001284087],"study_design_candidate":"not_applicable","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00041858485,0.00013899202,0.0049286033,0.00080154126,0.00036384343,0.00014254643,0.001315457,0.05301358,0.47903973,0.005187852,0.4100421,0.044607177],"study_design_scores_gemma":[0.0013861527,0.00015107954,0.0021126105,0.00022726221,0.000035627756,0.000012090766,0.00019491962,0.35285926,0.06445956,0.0010589447,0.57699287,0.00050962163],"about_ca_topic_score_codex":0.00001533145,"about_ca_topic_score_gemma":0.000034412897,"teacher_disagreement_score":0.41458017,"about_ca_system_score_codex":0.00015043547,"about_ca_system_score_gemma":0.00010878894,"threshold_uncertainty_score":0.83970195},"labels":[],"label_agreement":null},{"id":"W4416392647","doi":"10.1515/nanoph-2025-0388","title":"Cross‐polarized and stable second harmonic generation from monocrystalline copper","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Spectroscopy and Quantum Chemical Studies","field":"Physics and Astronomy","cited_by":1,"is_retracted":false,"has_abstract":true,"route_ca_aff":false,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"","funders":"Laidlaw Foundation; Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung","keywords":"Monocrystalline silicon; Nanomaterials; Nanophotonics; Second-harmonic generation; Femtosecond; Plasmon; Nonlinear optics; Copper; High harmonic generation; Anisotropy","score_opus":0.011783244819737224,"score_gpt":0.2677655421850918,"score_spread":0.25598229736535455,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4416392647","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9922426,0.0019497391,0.0010698723,0.00013637592,0.00019314117,0.00014328073,0.00019279131,0.000027163633,0.0040450594],"genre_scores_gemma":[0.99416447,0.000056291046,0.0020452484,0.00018447699,0.0000805844,0.000031323554,0.00012710507,0.000010162311,0.0033003355],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.99922407,0.000014575498,0.00019434522,0.0002788525,0.000076163014,0.0002119928],"domain_scores_gemma":[0.9996449,0.000048415346,0.000050897575,0.00016577443,0.000045895475,0.000044123764],"candidate_categories":["insufficient_payload"],"consensus_categories":[],"category_scores_codex":[0.000063529566,0.0001432262,0.00020984991,0.000015923912,0.0002148081,0.000107124484,0.00008144624,0.000058268863,0.0010964962],"category_scores_gemma":[0.0000056331,0.00013223206,0.000052798634,0.000104560626,0.000058540136,0.00009158525,0.000082315506,0.00015120291,0.000009789637],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000038191294,0.00006142095,0.018171107,0.0000070280253,0.00012471888,3.9459422e-7,0.00007214873,0.000004256358,0.97187334,0.00720583,0.0021891315,0.000252439],"study_design_scores_gemma":[0.0013162979,0.000022994871,0.0018222634,0.000014695306,0.000044625373,8.555205e-8,0.00005011869,0.007513026,0.914145,0.007879857,0.06700058,0.00019043323],"about_ca_topic_score_codex":0.00043272763,"about_ca_topic_score_gemma":0.000032737025,"teacher_disagreement_score":0.06481145,"about_ca_system_score_codex":0.000035636505,"about_ca_system_score_gemma":0.00005492617,"threshold_uncertainty_score":0.99981666},"labels":[],"label_agreement":null},{"id":"W4416392831","doi":"10.1515/nanoph-2025-0296","title":"Online training and pruning of multi‐wavelength photonic neural networks","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Neural Networks and Reservoir Computing","field":"Computer Science","cited_by":1,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Queen's University","funders":"Office of Naval Research; CMC Microsystems; Natural Sciences and Engineering Research Council of Canada; Andlinger Center for Energy and the Environment, Princeton University; State of New Jersey Department of Health; New Jersey Health Foundation","keywords":"Scalability; Photonics; Pruning; Artificial neural network; Multiplexing; Energy consumption; Reduction (mathematics); Resonator; Photonic integrated circuit","score_opus":0.023210820063934136,"score_gpt":0.2646748814792688,"score_spread":0.2414640614153347,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4416392831","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.8708777,0.0039131646,0.12294735,0.0004236305,0.0010473396,0.0003183327,0.0000025450533,0.0001782864,0.0002916658],"genre_scores_gemma":[0.9308086,0.0002779312,0.06828969,0.00042275919,0.000027254093,0.0000043609903,0.0000026024188,0.0000115550065,0.00015521678],"study_design_codex":"design_other","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9984638,0.00007056813,0.00040390965,0.00044616568,0.00017178946,0.0004437747],"domain_scores_gemma":[0.99896806,0.000235151,0.00016337182,0.00045795244,0.00008926325,0.00008620745],"candidate_categories":[],"consensus_categories":[],"category_scores_codex":[0.00030450075,0.00019701889,0.00034652444,0.00010241303,0.00019150342,0.000091473994,0.00071049813,0.00012360771,0.0000019494535],"category_scores_gemma":[0.00004686481,0.00017447486,0.00008849338,0.0007296426,0.00007993417,0.00017291498,0.000625853,0.00038693607,2.4922056e-7],"study_design_candidate":"simulation_or_modeling","study_design_consensus":null,"about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000031308897,0.00041997625,0.002166917,0.0001977669,0.00014503354,0.00008495417,0.0020741585,0.30264267,0.00554353,0.01263273,0.00020848094,0.6738525],"study_design_scores_gemma":[0.00054664264,0.0000669042,0.00080580794,0.0001284551,0.000009614267,0.000015282278,0.000065910404,0.9963366,0.00060206174,0.0001487047,0.0011163243,0.00015771808],"about_ca_topic_score_codex":0.000026418898,"about_ca_topic_score_gemma":0.00003050235,"teacher_disagreement_score":0.69369394,"about_ca_system_score_codex":0.0000268937,"about_ca_system_score_gemma":0.000101314385,"threshold_uncertainty_score":0.7114878},"labels":[],"label_agreement":null},{"id":"W4416392862","doi":"10.1515/nanoph-2025-0505","title":"High pump depletion second‐harmonic generation using domain engineered thin‐film lithium niobate waveguides","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Photorefractive and Nonlinear Optics","field":"Physics and Astronomy","cited_by":0,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":false,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Advanced Micro Devices (Canada)","funders":"National Key Research and Development Program of China; Natural Science Foundation of Jiangsu Province; National Natural Science Foundation of China","keywords":"Lithium niobate; Nonlinear system; Nonlinear optics; Quasi-phase-matching; Domain engineering; Domain (mathematical analysis); Energy transformation; Fabrication; Energy conversion efficiency","score_opus":0.01496069162661515,"score_gpt":0.25605911274610227,"score_spread":0.24109842111948712,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4416392862","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9798143,0.00015208356,0.016170938,0.0001074634,0.0009625879,0.0003242039,0.00014860767,0.0000581821,0.002261652],"genre_scores_gemma":[0.97319376,0.00002458981,0.02415846,0.00032394956,0.0003216853,0.000034029323,0.00031019913,0.000037029513,0.001596283],"study_design_codex":"bench_or_experimental","study_design_gemma":"bench_or_experimental","domain_scores_codex":[0.9986614,0.0000681335,0.00037237862,0.00036301767,0.00018358917,0.00035146475],"domain_scores_gemma":[0.99916047,0.000057691323,0.00014370524,0.0003775851,0.000167216,0.00009334735],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00026907766,0.00025712105,0.00028207834,0.00010329562,0.00023659703,0.00011280612,0.00018227885,0.00013066236,0.00041151847],"category_scores_gemma":[0.00001880259,0.00025906292,0.00013987605,0.00032455288,0.000037388665,0.00021990135,0.000076410186,0.00029963395,0.00003780842],"study_design_candidate":"bench_or_experimental","study_design_consensus":"bench_or_experimental","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.000039950624,0.00017572887,0.000567509,0.00003497211,0.000210277,0.000004546605,0.000220475,0.001826562,0.9852667,0.009517747,0.0017514096,0.00038414146],"study_design_scores_gemma":[0.00074523926,0.000035103963,0.000117584284,0.000037807848,0.000066433335,0.0000012629297,0.00010893065,0.20153153,0.7659419,0.0034891926,0.027647657,0.00027731268],"about_ca_topic_score_codex":0.00021125215,"about_ca_topic_score_gemma":0.000021647422,"teacher_disagreement_score":0.21932474,"about_ca_system_score_codex":0.00015919008,"about_ca_system_score_gemma":0.00036226117,"threshold_uncertainty_score":0.9999862},"labels":[],"label_agreement":null},{"id":"W4416933770","doi":"10.1515/nanoph-2025-0437","title":"A comprehensive study of plasmonic mode hybridization in gold nanoparticle‐over‐mirror (NPoM) arrays","year":2025,"lang":"en","type":"article","venue":"Nanophotonics","topic":"Plasmonic and Surface Plasmon Research","field":"Engineering","cited_by":2,"is_retracted":false,"has_abstract":true,"route_ca_aff":true,"route_ca_fund":true,"route_ca_venue":false,"route_about_ca":false,"ca_institutions":"Institut National de la Recherche Scientifique; University of Waterloo; Institut interdisciplinaire d'innovation technologique; Université de Sherbrooke","funders":"Natural Sciences and Engineering Research Council of Canada","keywords":"Plasmon; Dephasing; Surface plasmon; Surface plasmon polariton; Coupling (piping); Nanophotonics; Dielectric","score_opus":0.01585205408155425,"score_gpt":0.2768992485614018,"score_spread":0.26104719447984753,"validation_status":"score_only:v0-immature-baseline","prediction":{"id":"W4416933770","genre_codex":"empirical","genre_gemma":"empirical","domain_codex":null,"domain_gemma":null,"model_version":"codex-gemma-dda1882f352a","genre_candidate":"empirical","genre_consensus":"empirical","domain_candidate":null,"domain_consensus":null,"prediction_status":"machine_predicted_unvalidated","genre_scores_codex":[0.9965538,0.00043044478,0.00008247066,0.000023220222,0.0002957965,0.0007425993,0.000027179287,0.00013342184,0.0017110883],"genre_scores_gemma":[0.9980275,0.00020446752,0.0013205858,0.00002537103,7.813604e-7,0.0000816836,0.000008418479,0.000031380514,0.00029979346],"study_design_codex":"simulation_or_modeling","study_design_gemma":"simulation_or_modeling","domain_scores_codex":[0.9982196,0.000074155345,0.00053987425,0.0003123492,0.00038266112,0.00047132597],"domain_scores_gemma":[0.9991165,0.00021856237,0.00005008406,0.00043217486,0.00010709374,0.00007558886],"candidate_categories":["metaepi_narrow"],"consensus_categories":[],"category_scores_codex":[0.00014831683,0.0002322149,0.00044227848,0.0002657689,0.000044424225,0.000030272065,0.0003195603,0.00013356109,0.00002565645],"category_scores_gemma":[0.000055223645,0.00024893787,0.00006279295,0.0010536275,0.000047179852,0.00013279085,0.0000961947,0.0003547606,0.000021894035],"study_design_candidate":"simulation_or_modeling","study_design_consensus":"simulation_or_modeling","about_ca_topic_candidate":false,"about_ca_topic_consensus":false,"about_ca_system_candidate":false,"about_ca_system_consensus":false,"study_design_scores_codex":[0.00019158864,0.0008368512,0.017533926,0.00031138933,0.00016964223,0.000054604476,0.0014573599,0.60220927,0.37555602,0.0002999997,0.0010243711,0.00035496327],"study_design_scores_gemma":[0.002444929,0.00015635385,0.007343059,0.00008388558,0.000021677668,0.0000015559581,0.0009036155,0.867848,0.11959612,0.00015575373,0.0012223274,0.00022274625],"about_ca_topic_score_codex":0.00027950507,"about_ca_topic_score_gemma":0.0006090929,"teacher_disagreement_score":0.2656387,"about_ca_system_score_codex":0.00023476052,"about_ca_system_score_gemma":0.00013879896,"threshold_uncertainty_score":0.9999963},"labels":[],"label_agreement":null}]}