| Functionalized graphene enables highly efficient solar thermal steam generation J Yang, Y Pang, W Huang, SK Shaw, J Schiffbauer, MA Pillers, X Mu, ... ACS nano 11 (6), 5510-5518, 2017 | 367 | 2017 |
| Thermal transport in graphene oxide–from ballistic extreme to amorphous limit X Mu, X Wu, T Zhang, DB Go, T Luo Scientific reports 4 (1), 3909, 2014 | 289 | 2014 |
| Polymer nanofibers with outstanding thermal conductivity and thermal stability: fundamental linkage between molecular characteristics and macroscopic thermal properties T Zhang, X Wu, T Luo The Journal of Physical Chemistry C 118 (36), 21148-21159, 2014 | 206 | 2014 |
| Role of chain morphology and stiffness in thermal conductivity of amorphous polymers T Zhang, T Luo The Journal of Physical Chemistry B 120 (4), 803-812, 2016 | 176 | 2016 |
| Hydrogenation of penta-graphene leads to unexpected large improvement in thermal conductivity X Wu, V Varshney, J Lee, T Zhang, JL Wohlwend, AK Roy, T Luo Nano letters 16 (6), 3925-3935, 2016 | 165 | 2016 |
| Molecular bridge enables anomalous enhancement in thermal transport across hard‐soft material interfaces F Sun, T Zhang, MM Jobbins, Z Guo, X Zhang, Z Zheng, D Tang, ... Advanced Materials 26 (35), 6093-6099, 2014 | 158 | 2014 |
| Morphology-influenced thermal conductivity of polyethylene single chains and crystalline fibers T Zhang, T Luo Journal of Applied Physics 112 (9), 2012 | 123 | 2012 |
| Crystalline polymer nanofibers with ultra-high strength and thermal conductivity R Shrestha, P Li, B Chatterjee, T Zhang, X Wu, Z Liu, T Luo, S Choi, ... Nature communications 9 (1), 1664, 2018 | 117 | 2018 |
| Role of hydrogen bonds in thermal transport across hard/soft material interfaces T Zhang, AR Gans-Forrest, E Lee, X Zhang, C Qu, Y Pang, F Sun, T Luo ACS applied materials & interfaces 8 (48), 33326-33334, 2016 | 103 | 2016 |
| High-contrast, reversible thermal conductivity regulation utilizing the phase transition of polyethylene nanofibers T Zhang, T Luo ACS nano 7 (9), 7592-7600, 2013 | 98 | 2013 |
| Giant thermal rectification from polyethylene nanofiber thermal diodes T Zhang, T Luo Small 11 (36), 4657-4665, 2015 | 81 | 2015 |
| Coherent and incoherent phonon thermal transport in isotopically modified graphene superlattices X Mu, T Zhang, DB Go, T Luo Carbon 83, 208-216, 2015 | 78 | 2015 |
| Thermal energy transport across hard–soft interfaces X Wei, T Zhang, T Luo ACS Energy Letters 2 (10), 2283-2292, 2017 | 75 | 2017 |
| Chain conformation-dependent thermal conductivity of amorphous polymer blends: the impact of inter-and intra-chain interactions X Wei, T Zhang, T Luo Physical Chemistry Chemical Physics 18 (47), 32146-32154, 2016 | 73 | 2016 |
| Nanostructures significantly enhance thermal transport across solid interfaces E Lee, T Zhang, T Yoo, Z Guo, T Luo ACS applied materials & interfaces 8 (51), 35505-35512, 2016 | 54 | 2016 |
| High-contrast and reversible polymer thermal regulator by structural phase transition R Shrestha, Y Luan, S Shin, T Zhang, X Luo, JS Lundh, W Gong, ... Science advances 5 (12), eaax3777, 2019 | 46 | 2019 |
| Dual-mode solid-state thermal rectification R Shrestha, Y Luan, X Luo, S Shin, T Zhang, P Smith, W Gong, ... Nature Communications 11 (1), 4346, 2020 | 45 | 2020 |
| Thermal boundary conductance enhancement using experimentally achievable nanostructured interfaces–analytical study combined with molecular dynamics simulation E Lee, T Zhang, M Hu, T Luo Physical Chemistry Chemical Physics 18 (25), 16794-16801, 2016 | 37 | 2016 |
| Origin of hydrophilic surface functionalization-induced thermal conductance enhancement across solid–water interfaces D Huang, R Ma, T Zhang, T Luo ACS applied materials & interfaces 10 (33), 28159-28165, 2018 | 33 | 2018 |
| Determining influential descriptors for polymer chain conformation based on empirical force-fields and molecular dynamics simulations R Ma, D Huang, T Zhang, T Luo Chemical Physics Letters 704, 49-54, 2018 | 32 | 2018 |
Tengfei LuoDorini Family Professor, MÖNSTER (MOlecular/Nano-Sacle Transport & Energy Research) Labnd.eduÀÇ À̸ÞÀÏ È®ÀεÊ
