| Thermal conductivity of silicene calculated using an optimized Stillinger-Weber potential X Zhang, H Xie, M Hu*, H Bao*, S Yue, G Qin, G Su Physical Review B 89 (5), 054310, 2014 | 295 | 2014 |
| Significant Reduction of Thermal Conductivity in Si/Ge Core− Shell Nanowires M Hu*, KP Giapis, JV Goicochea, X Zhang, D Poulikakos Nano letters 11 (2), 618-623, 2010 | 270 | 2010 |
| Anomalous thermal response of silicene to uniaxial stretching M Hu*, X Zhang, D Poulikakos Physical Review B 87 (19), 195417, 2013 | 233 | 2013 |
| Thermal conductivity of zeolitic imidazolate framework-8: a molecular simulation study X Zhang, J Jiang* The Journal of Physical Chemistry C 117 (36), 18441-18447, 2013 | 137 | 2013 |
| Thermal conductivity reduction in core-shell nanowires M Hu*, X Zhang, KP Giapis, D Poulikakos Physical Review B 84 (8), 085442, 2011 | 131 | 2011 |
| Resonant bonding driven giant phonon anharmonicity and low thermal conductivity of phosphorene G Qin, X Zhang, SY Yue, Z Qin, H Wang, Y Han, M Hu* Physical Review B 94 (16), 165445, 2016 | 129 | 2016 |
| Quantitatively analyzing phonon spectral contribution of thermal conductivity based on nonequilibrium molecular dynamics simulations. I. From space Fourier transform Y Zhou#, X Zhang#, M Hu* Physical Review B 92 (19), 195204, 2015 | 115 | 2015 |
| Bilateral substrate effect on the thermal conductivity of two-dimensional silicon X Zhang, H Bao*, M Hu* Nanoscale 7, 6014-6022, 2015 | 90 | 2015 |
| Tuning thermal conductivity of crystalline polymer nanofibers by interchain hydrogen bonding L Zhang, M Ruesch, X Zhang, Z Bai, L Liu* RSC Advances 5 (107), 87981-87986, 2015 | 72 | 2015 |
| Ultra-low thermal conductivity and high thermoelectric performance of two-dimensional triphosphides (InP 3, GaP 3, SbP 3 and SnP 3): a comprehensive first-principles study Z Sun, K Yuan, Z Chang, S Bi, X Zhang, D Tang Nanoscale 12 (5), 3330-3342, 2020 | 71 | 2020 |
| Low thermal conductivity of graphyne nanotubes from molecular dynamics study M Hu*, Y Jing, X Zhang Physical Review B 91 (15), 155408, 2015 | 71 | 2015 |
| Large “near junction” thermal resistance reduction in electronics by interface nanoengineering M Hu, X Zhang, D Poulikakos*, CP Grigoropoulos International Journal of Heat and Mass Transfer 54 (25), 5183-5191, 2011 | 71 | 2011 |
| Nonmonotonic Diameter Dependence of Thermal Conductivity of Extremely Thin Si Nanowires: Competition between Hydrodynamic Phonon Flow and Boundary Scattering Y Zhou, X Zhang, M Hu* Nano Letters 17, 1269−1276, 2017 | 70 | 2017 |
| Insight into the collective vibrational modes driving ultralow thermal conductivity of perovskite solar cells SY Yue#, X Zhang#, G Qin, J Yang, M Hu* Physical Review B 94 (11), 115427, 2016 | 68 | 2016 |
| Molecular Origin of Electric Double-Layer Capacitance at Multilayer Graphene Edges H Yang, X Zhang, J Yang, Z Bo*, M Hu*, J Yan, K Cen The Journal of Physical Chemistry Letters 8, 153-160, 2016 | 65 | 2016 |
| An excellent candidate for largely reducing interfacial thermal resistance: a nano-confined mass graded interface Y Zhou, X Zhang, M Hu* Nanoscale 8 (4), 1994-2002, 2016 | 65 | 2016 |
| Effects of tensile strain and finite size on the thermal conductivity in monolayer WSe2 K Yuan, X Zhang*, L Li*, D Tang* Physical Chemistry Chemical Physics 21, 468--477, 2018 | 64 | 2018 |
| Thermal rectification at silicon/horizontally aligned carbon nanotube interfaces X Zhang, M Hu, D Tang* Journal of Applied Physics 113 (19), 194307, 2013 | 64 | 2013 |
| Thermal transport crossover from crystalline to partial-crystalline partial-liquid state Y Zhou*, S Xiong*, X Zhang, S Volz*, M Hu* Nature Communications 9 (1), 4712, 2018 | 55 | 2018 |
| A Low-Frequency Wave Motion Mechanism Enables Efficient Energy Transport in Carbon Nanotubes at High Heat Fluxes X Zhang, M Hu*, D Poulikakos Nano letters 12 (7), 3410-3416, 2012 | 53 | 2012 |
Ming HuUniversity of South CarolinaVerified email at sc.edu
