| Lattice thermal conductivity evaluated using elastic properties T Jia, G Chen, Y Zhang Physical Review B 95 (15), 155206, 2017 | 139 | 2017 |
| Screening promising thermoelectric materials in binary chalcogenides through high-throughput computations T Jia, Z Feng, S Guo, X Zhang, Y Zhang ACS applied materials & interfaces 12 (10), 11852-11864, 2020 | 63 | 2020 |
| Dual effects of lone-pair electrons and rattling atoms in on its ultralow thermal conductivity Z Feng, T Jia, J Zhang, Y Wang, Y Zhang Physical Review B 96 (23), 235205, 2017 | 59 | 2017 |
| Electrical property dominated promising half-Heusler thermoelectrics through high-throughput material computations S Guo, T Jia, Y Zhang The Journal of Physical Chemistry C 123 (31), 18824-18833, 2019 | 39 | 2019 |
| Thermoelectric optimization of by defect engineering for room-temperature applications Z Feng, X Zhang, Y Wang, J Zhang, T Jia, B Cao, Y Zhang Physical Review B 99 (15), 155203, 2019 | 38 | 2019 |
| Prediction of improved thermoelectric performance by ordering in double half-Heusler materials S Guo, Z Liu, Z Feng, T Jia, S Anand, GJ Snyder, Y Zhang Journal of Materials Chemistry A 8 (44), 23590-23598, 2020 | 37 | 2020 |
| Dirac cone move and bandgap on/off switching of graphene superlattice TT Jia, MM Zheng, XY Fan, Y Su, SJ Li, HY Liu, G Chen, Y Kawazoe Scientific reports 6 (1), 18869, 2016 | 31 | 2016 |
| Band gap on/off switching of silicene superlattice TT Jia, MM Zheng, XY Fan, Y Su, SJ Li, HY Liu, G Chen, Y Kawazoe The Journal of Physical Chemistry C 119 (35), 20747-20754, 2015 | 24 | 2015 |
| Indirect–direct bandgap transition and gap width tuning in bilayer MoS2 superlattices JT Jiang, SL Xiu, MM Zheng, TT Jia, HY Liu, Y Zhang, G Chen Chemical Physics Letters 613, 74-79, 2014 | 23 | 2014 |
| Silicene nanomeshes: bandgap opening by bond symmetry breaking and uniaxial strain TT Jia, XY Fan, MM Zheng, G Chen Scientific reports 6 (1), 20971, 2016 | 22 | 2016 |
| Localized dimers drive strong anharmonicity and low lattice thermal conductivity in T Jia, J Carrete, Z Feng, S Guo, Y Zhang, GKH Madsen Physical Review B 102 (12), 125204, 2020 | 20 | 2020 |
| Band engineering SnTe via trivalent substitutions for enhanced thermoelectric performance X Zhang, Z Wang, B Zou, MK Brod, J Zhu, T Jia, G Tang, GJ Snyder, ... Chemistry of Materials 33 (24), 9624-9637, 2021 | 17 | 2021 |
| Band structure modification of the thermoelectric Heusler-phase TiFe 2 Sn via Mn substitution T Zou, T Jia, W Xie, Y Zhang, M Widenmeyer, X Xiao, A Weidenkaff Physical Chemistry Chemical Physics 19 (28), 18273-18278, 2017 | 10 | 2017 |
| Chemical trends in the high thermoelectric performance of the pyrite-type dichalcogenides , and T Jia, J Carrete, GKH Madsen, Y Zhang, SH Wei Physical Review B 105 (24), 245203, 2022 | 7 | 2022 |
| Origin of the variation in lattice thermal conductivities in pyrite-type dichalcogenides T Jia, X Liu, Y Zhang, SH Wei Physical Review B 107 (11), 115204, 2023 | 4 | 2023 |
| First principles investigation of intrinsic and Na defects in XTe (X= Ca, Sr, Ba) nanostructured PbTe X Zhang, MY Toriyama, JP Male, Z Feng, S Guo, T Jia, Z Ti, GJ Snyder, ... Materials Today Physics 19, 100415, 2021 | 4 | 2021 |
| Excellent thermoelectric performances of pressure synthesized ZnSe2 T Jia, J Carrete, Z Feng, S Guo, Y Zhang, GKH Madsen arXiv preprint arXiv:1912.10603, 2019 | 2 | 2019 |
| Geometrically induced π-band splitting in graphene superlattices Y Wei, T Jia, G Chen Chinese Physics B 26 (2), 028103, 2017 | 2 | 2017 |
| Unveiling disparities and promises of Cu and Ag chalcopyrites for thermoelectrics HP Liang, S Geng, T Jia, CN Li, X Xu, X Zhang, SH Wei Physical Review B 109 (3), 035205, 2024 | 1 | 2024 |
| Low thermal conductivities and excellent thermoelectric performances of the pyrite-type IIB-VIA2 dichalcogenides: ZnS2, CdS2 and CdSe2 T Jia, J Carrete, Y Zhang, GKH Madsen | | |
Yongsheng ZhangQufu Normal University; Institute of Solid State Physics, CAS在 qfnu.edu.cn 的电子邮件经过验证
