{"id":6,"date":"2020-09-17T02:59:16","date_gmt":"2020-09-17T02:59:16","guid":{"rendered":"https:\/\/sites.gc.sjtu.edu.cn\/huabao\/?page_id=6"},"modified":"2025-10-09T14:16:07","modified_gmt":"2025-10-09T14:16:07","slug":"publications-%e8%ae%ba%e6%96%87","status":"publish","type":"page","link":"https:\/\/sites.gc.sjtu.edu.cn\/hua-bao\/publications-%e8%ae%ba%e6%96%87\/","title":{"rendered":"Publications \u8bba\u6587"},"content":{"rendered":"

Journal Papers:<\/strong><\/span><\/h2>\n

(* denotes the corresponding author)<\/span><\/p>\n

Reviews:<\/strong><\/span><\/h3>\n

[88] (Review)<\/strong> Han Wei, Hua Bao*<\/span><\/span>, Xiulin Ruan*<\/span><\/span>, Perspective: Predicting and optimizing thermal transport properties with machine learning methods, Energy and AI<\/em><\/strong>, 8, 100153, 2022 (link<\/a>)<\/span><\/p>\n

[81] (Review) <\/strong>Xiaokun Gu, Zheyong Fan, Hua Bao*<\/span><\/span>, Thermal conductivity prediction by atomistic simulation methods: Recent advances and detailed comparison, Journal of Applied Physics<\/em><\/strong>, 130, 210902, 2021 (link<\/a>)<\/span><\/p>\n

[42]\u00a0(Review)<\/strong>\u00a0Hua Bao*, Jie Chen*, Xiaokun Gu*, Bingyang Cao*, A Review of Simulation Methods for Micro\/Nanoscale Heat Conduction,\u00a0ES Energy & Environment<\/em><\/strong>, 1, 16-55,\u00a02018\u00a0(link<\/a>)<\/span><\/p>\n

[28]\u00a0(Review)<\/strong> Cheng Shao, Xiaoxiang Yu, Nuo Yang, Yanan Yue, Hua Bao*, A review of thermal transport in low-dimensional materials under external perturbation: effect of strain, substrate, and clustering,\u00a0Nanoscale and Microscale Thermophysical Engineering<\/em><\/strong>, 21, 1-36, 2017 (link<\/a>)<\/span><\/p>\n

2025<\/span><\/em><\/strong><\/h3>\n

[137] Kunlang Bu, Hua Bao*, Design of low-thickness random nanoparticle coatings for radiative cooling using particle swarm optimization<\/span>. International Journal of Thermal Sciences<\/em><\/strong>\u00a0 218, 110167, 2025 (link<\/a>).<\/span><\/p>\n

[136] Yonglin Xia, Yufei Sheng, Ru Jia, Jiaxuan Xu, Hua Bao*, Non-Fourier thermal analysis of the self-heating effect in CMOS logic circuits<\/span>. APL Electronic Devices<\/em><\/strong> 1, 036115, 2025 (link<\/a>).<\/span><\/p>\n

[135] Shuying Wang, Yufei Sheng, Yonglin Xia, Hua Bao, Pengpeng Ren*, Runsheng Wang, Zhigang Ji*, Dealing with coupling effect for accurate thermal profile prediction of BEOL interconnect in advanced technology nodes<\/span>. APL Electronic Devices<\/em><\/strong> 1, 036108, 2025 (link<\/a>).<\/span><\/p>\n

[134] Yufei Sheng, Yonglin Xia, Jiaxuan Xu, Shuying Wang, Pengpeng Ren, Zhigang Ji, Hua Bao, Multiscale Thermal Simulation for GAAFET With First-Principles-Based Boltzmann Transport Equation<\/span>. IEEE Transactions on Electron Devices<\/strong><\/em> 72, 4700\u00a0– 4707, 2025 (link<\/a>).<\/span><\/p>\n

[133] Yifan Yang, Yushi Chen, Zhen Shen, Hanxuan Zeng, Leshan Shen, Chenxi Li, Zhifu Qi, Zhouyang Luo*, Hua Bao*, Optimizing the distiller structural design for solar interfacial desalination<\/span>. Desalination<\/strong><\/em> 614, 119190, 2025 (link<\/a>).<\/span><\/p>\n

[132] Shuo Cao, Ao Wang*, Zheyong Fan*, Hua Bao, Ping Qian, Ye Su*, Yu Yan, Lattice thermal conductivity of 16 elemental metals from molecular dynamics simulations with a unified neuroevolution potential<\/span>. Journal of Applied Physics<\/strong><\/em> 137, 225101, 2025 (link<\/a>).<\/span><\/p>\n

[131] Jiaxuan Xu, Yufei Sheng, Zhongyong Wang, Hua Bao, Isovalent Doping Reduces Channel Temperature Within Nanoscale Devices<\/span>. IEEE <\/strong><\/em>Transactions on Electron Devices\u00a0<\/em><\/strong>72, 4333 – 4339, 2025 (link<\/a>).<\/span><\/p>\n

[130] Han Xie, Ru Jia, Yonglin Xia, Lei Li, Yue Hu, Jiaxuan Xu, Yufei Sheng, Yuanyuan Wang, Hua Bao*, An ab initio dataset of size-dependent effective thermal conductivity for advanced technology transistors<\/span>. Chinese Physics B\u00a0<\/em><\/strong>34, 046501, 2025 (link<\/a>).<\/span><\/p>\n

[129] Yufei Sheng, Hongxin Zhu, Siqi Xie, Qian Lv, Huaqing Xie, Haidong Wang*, Ruitao Lv*, Hua Bao*, <\/span>Electrically-driven reversible phonon transport manipulation in two-dimensional heterostructures<\/span>. Nature Communications <\/em><\/strong>16, 1970, 2025 (link<\/a>).<\/span><\/p>\n

[128] Yushi Chen, Leshan Shen, Zhifu Qi, Zhouyang Luo*, Xiangyu Li*, Hua Bao*, Large-scale implementation of solar interfacial desalination. Nature Sustainability <\/em><\/strong>1-8, 2025 (link<\/a>).<\/span><\/p>\n

[127] Wenyi Cai, Kunlang Bu, Lingyan Zha, Jingjin Zhang, Dayi Lai, Hua Bao*, Energy consumption of plant factory with artificial light: Challenges and opportunities. Renewable and Sustainable Energy Reviews <\/em><\/strong>210, 115235, 2025 (link<\/a>).<\/span><\/p>\n

[126] Ru Jia, Yufei Sheng, Jiaxuan Xu, Han Xie, Hua Bao*, The effective thermal conductivity of micro\/nanofilm under different heating conditions using nongray Boltzmann transport equation. International Journal of Thermal Sciences <\/em><\/strong>208, 109446, 2025 (link<\/a>).<\/span><\/p>\n

[125] Jiaxuan Xu, Xiaona Huang, Yufei Sheng, Qiangsheng Sun, Hongkai Zhang, Hua Bao*, Yanan Yue*, Direct Observation of Substantial Phonon Nonequilibrium Near Nanoscale Hotspots in Gallium Nitride. Advanced Science <\/em><\/strong>2411040, 2025 (link<\/a>).<\/span><\/p>\n

[124] Wenyi Cai, Saiya Li, Lingyan Zha, Junyi He, Jingjin Zhang, Hua Bao*, Significantly enhanced energy efficiency through reflective materials integration in plant factories with artificial light. Applied Energy <\/em><\/strong>377, 124587, 2025 (link<\/a>).<\/span><\/p>\n

2024<\/span><\/em><\/strong><\/h3>\n

[123] Xinyu Zhang, Cheng Shao*, Hua Bao*, Cryogenic thermal transport properties from accelerated first-principles calculations: Role of boundary and isotope scattering. Physical Review B <\/em><\/strong>110, 224301, 2024 (link<\/a>).<\/span><\/p>\n

[122] Yushi Chen, Hanxuan Zeng, Hao Peng, Zhouyang Luo*, Hua Bao*, Synergistic solar electricity-water generation through an integration of semitransparent solar cells and multistage interfacial desalination. Renewable Energy <\/em><\/strong>237, 121837, 2024 (link<\/a>).<\/span><\/p>\n

[121] Yonglin Xia, Xinyu Zhang, Ao Wang, Yufei Sheng, Han Xie*, Hua Bao*, Critical factors influencing electron and phonon thermal conductivity in metallic materials using first-principles calculations. Journal of Physics: Condensed Matter <\/em><\/strong>37, 055701, 2024 (link<\/a>).<\/span><\/p>\n

[120] Zhitong Yu, Kunlang Bu, Yongzi Liu, Aojiang Wang, Wei Yuan, Jiao Xue, Jingjin Zhang, Hua Bao, Dayi Lai*, Energy examination and optimization workflow for container farms: A case study in Shanghai, China. Applied Energy <\/em><\/strong>374, 124038, 2024 (link<\/a>).<\/span><\/p>\n

[119] Xinyu Zhang, Ao Wang, Cheng Shao*, Hua Bao*, <\/span>Understanding thermal transport in magnesium solid solutions through first-principles approaches and machine learning feature screening. <\/span>Acta Materialia <\/span><\/span><\/strong><\/em>276, 120160, 2024 (link<\/a>).<\/span><\/span><\/span><\/p>\n

[118] Xiaoming Wang, Jiajing He, Ao Wang, Kun Zhang, Yufei Sheng, Weida Hu, Chaoyuan Jin, Hua Bao, Yaping Dan*, Analytical Impact-Excitation Theory of Er\/O\/B Codoped Si Light-Emitting Diodes. Physical Review Letters<\/em><\/strong> 132, 246901, 2024 (link<\/a>).<\/span><\/p>\n

[117] Kunlang Bu, Zhitong Yu, Dayi Lai, Hua Bao*, Energy-saving effect assessment of various factors in container plant factories: A data-driven random forest approach. Cleaner Energy System<\/strong>s<\/strong><\/em> 8, 100122, 2024 (link<\/a>).<\/span><\/p>\n

[116] Ao Wang, Hua Bao*, Size-dependent thermal transport properties of advanced metallic nanowire interconnects. Applied Physics Letters<\/strong><\/em> 124, 212202, 2024 (link<\/a>).<\/span><\/p>\n

[115] Yue Hu, Jiaxuan Xu, Xiulin Ruan, Hua Bao*, Defect scattering can lead to enhanced phonon transport at nanoscale. Nature Communications<\/strong><\/em> 15, 3304, 2024 (link<\/a>).<\/span><\/p>\n

[114] Xiao Luo, Long Jiao, Yunlong Guo, Hua Bao, Changying Zhao, Xiaokun Gu*, Ultrahigh freshwater production achieved by unidirectional heat transfer interfacial evaporation solar still integrated with waste heat recovery. Energy Conversion and Management<\/strong><\/em> 304, 118226, 2024 (link<\/a>).<\/span><\/p>\n

[113] Yufei Sheng, Shuying Wang, Yue Hu, Jiaxuan Xu, Zhigang Ji*, Hua Bao*, Integrating First-Principles-Based Non-Fourier Thermal Analysis Into Nanoscale Device Simulation. IEEE Transactions on Electron Devices<\/strong><\/em> 71, 1769, 2024 (link<\/a>).<\/span><\/p>\n

[112] Long Jiao, Xiao Luo, Lingyan Zha, Hua Bao*, Jingjin Zhang*, Xiaokun Gu*, Machine learning assisted water management strategy on a self-sustaining seawater desalination and vegetable cultivation platform. Computers and Electronics in Agriculture<\/strong><\/em> 217, 108569, 2024 (link<\/a>).<\/span><\/p>\n

[111] Pengli Li, Yijie Liu, Xiangyu Liu, Ao Wang, Wenjie Liu, Naiqin Yi, Qi Kang, Meng He, Zhantao Pei, Jie Chen, Pingkai Jiang, Wei Li, Hua Bao, Xingyi Huang*, Reversed Yolk\u2013Shell Dielectric Scatterers for Advanced Radiative Cooling. Advanced Functional Materials<\/strong><\/em> 34, 2315658, 2024 (link<\/a>).<\/span><\/p>\n

2023<\/span><\/em><\/strong><\/h3>\n

[110] Yushi Chen, Xiao Luo, Xiaokun Gu, and Hua Bao*, The energy efficiency of multistage interfacial desalination: Comprehensive analysis and further improvement strategy. Desalination<\/strong><\/em>, 568, 117000, 2023 (link<\/a><\/em>).<\/em><\/span><\/p>\n

[109] Jiaxuan Xu, Han Wei, and Hua Bao*, Physics-informed neural networks for studying heat transfer in porous media. International Journal of Heat and Mass Transfer<\/strong>,<\/em> 217, 124671, 2023 (link<\/em><\/a>).<\/span><\/p>\n

[108] Yue Hu#<\/sup>, Ru Jia#<\/sup>, Jiaxuan Xu#<\/sup>, Yufei Sheng, Minhua Wen, James Lin, Yongxing Shen, and Hua Bao*,GiftBTE: an efficient deterministic solver for non-gray phonon Boltzmann transport equation. Journal of Physics: Condensed Matter<\/strong><\/em>, 36, 025901, 2023 (link<\/em><\/a>).<\/span><\/p>\n

[107] Kunlang Bu, Xingyi Huang, Xiangyu Li*, and Hua Bao*. Consistent Assessment of the Cooling Performance of Radiative Cooling Materials. Advanced Functional Materials<\/strong><\/em> 33, 2307191, 2023 (link<\/em><\/a>).<\/span><\/p>\n

[106] Ao Wang, Shou-Hang Li, Hua Bao*, Thermal transport mechanism of electrons and phonons in pristine and defective HfB2. Rare Metals<\/strong>,<\/em> 42, 3651\u20133661, 2023 (link<\/em><\/a>).<\/span><\/p>\n

[105] Honggang Zhang, Xiaokun Gu, Zheyong Fan, and Hua Bao*, Vibrational anharmonicity results in decreased thermal conductivity of amorphous HfO2 at high temperature. Physical Review B<\/strong>, 108, 045422, 2023 (link<\/a>).<\/i><\/span><\/p>\n

[104] Wenyi Cai, Xiao Luo, Zhentao Lian, Guo Chen, Hao-Chung Kuo, Hua Bao*, and Chang-Ching Tu*, Optical-Concentrating Solar Distillation Based on Three-Dimensional Copper Foam Cubes Coated with CuS Nanoparticles and Agarose Gel. ACS Applied Materials & Interfaces<\/strong><\/em>, 15, 20120-20129, 2023 (link<\/a>).<\/span><\/p>\n

[103] Jie Chen, Yao Zhou, Xingyi Huang*, Chunyang Yu, Donglin Han, Ao Wang, Yingke Zhu, Kunming Shi, Qi Kang, Pengli Li, Pingkai Jiang, Xiaoshi Qian, Hua Bao, Shengtao Li, Guangning Wu, Xinyuan Zhu, Qing Wang*,\u00a0Ladderphane copolymers for high-temperature capacitive energy storage. Nature<\/strong><\/em>, 615, 62-66, 2023 (link<\/a>).<\/span><\/p>\n

[102] Han Wei, Yue Hu, Hua Bao*, Influence of point defects and multiscale pores on the different phonon transport regimes, Communications Materials<\/strong><\/em>, 4, 3, 2023 (link<\/a>)<\/span><\/p>\n

[101] Kunlang Bu#<\/sup>, Junjie Fan#<\/sup>, Ao Wang, Hua Bao*, Enhanced dew harvest with porous wind covers, Solar Energy Materials and Solar Cells<\/strong><\/em>, 250, 112099, 2023 (link<\/a>)<\/span><\/p>\n

[100] Ao Wang, Shouhang Li, Tao Ying, Xiaoqin Zeng, Hua Bao*, First-principles based computational framework for the thermal conductivity of complex intermetallics: The case study of MgZn2<\/span> and Mg4<\/span>Zn7<\/span>, Journal of Applied Physics<\/strong><\/em>, 133, 015101, 2023 (link<\/a>)<\/span><\/p>\n

[99] Jiaxuan Xu, Yue Hu, Hua Bao*, Quantitative Analysis of Nonequilibrium Phonon Transport Near a Nanoscale Hotspot, Physical Review Applied<\/strong><\/em>, 19, 014007, 2023 (link<\/a>)<\/span><\/p>\n

2022<\/em><\/span><\/strong><\/h3>\n

[98] Xiao Luo, Xiaokun Gu*, Jincheng Shi, Changying Zhao, Hua Bao*, Thermal design strategy for enhanced freshwater harvesting with interfacial evaporation, Applied Thermal Engineering<\/strong><\/em>, 216,119104, 2022 (link<\/a>)<\/span><\/p>\n

[97] Wenjie Gao, Leshan Shen, Senshan Sun, Guilong Peng, Zhen Shen, Yunpeng Wang, AbdAllah Wagih Kandeal, Zhouyang Luo, AE Kabeel, Jianqun Zhang*, Hua Bao*, Nuo Yang*, Forecasting solar still performance from conventional weather data variation by machine learning method, Chinese Physics B<\/strong><\/em>, 2022 (link<\/a>)<\/span><\/p>\n

[96] Xinyu Zhang, Shouhang Li, Ao Wang, Hua Bao*, \u00a0Pressure-dependent thermal conductivity in Al, W, and Pt: Role of electrons and phonons, Physical Review B<\/em><\/strong>, 106, 094313, 2022 (link<\/a>)<\/span><\/p>\n

[95] Han Wei, Yue Hu, Hua Bao*, Xiulin Ruan*, Quantifying the diverse wave effects in thermal transport of nanoporous graphene, Carbon<\/em><\/strong>, 197, 18-26, 2022 (link<\/a>)<\/span><\/p>\n

[94] Yu Chen, Honggang Zhang, Jie Chen, Yiting Guo, Pingkai Jiang, Feng Gao, Hua Bao, Xingyi Huang*, Thermally Conductive but Electrically Insulating Polybenzazole Nanofiber\/Boron Nitride Nanosheets Nanocomposite Paper for Heat Dissipation of 5G Base Stations and Transformers, ACS nano<\/em><\/strong>, 16<\/span>,<\/span>\u00a014323\u201314333, <\/span>2022 (link<\/a>)<\/span><\/p>\n

[93] Yue Hu, Yongxing Shen, Hua Bao*, Optimized Phonon Band Discretization Scheme for Efficiently Solving the Nongray Boltzmann Transport Equation, Journal of Heat Transfer<\/strong><\/em>, 144, 072501, 2022 (link<\/a>)<\/span><\/p>\n

[92] Yue Hu, Yongxing Shen, Hua Bao*, Ultra-efficient and parameter-free computation of submicron thermal transport with phonon Boltzmann transport equation, Fundamental Research<\/em><\/strong>, 2022 (link<\/a>)<\/span><\/p>\n

[91] Honggang Zhang, Han Wei, Hua Bao*, Thermal Transport Mechanism of Amorphous HfO2<\/sub>: A Molecular Dynamics Based Study, Journal of Thermal Science<\/em><\/strong>, 31, 1052-1060, 2022 (link<\/a>)<\/span><\/p>\n

[90] Shouhang Li*, Zhen Tong, Cheng Shao, Hua Bao, Thomas Frauenheim, Xiangjun Liu*, Anomalously Isotropic Electron Transport and Weak Electron\u2013Phonon Interactions in Hexagonal Noble Metals, The Journal of Physical Chemistry Letters<\/em><\/strong>, 13, 4289-4296, 2022 (link<\/a>)<\/span><\/p>\n

[89] Zhen Tong#<\/sup>, Joseph Peoples#<\/sup>, Xiulin Li, Xiaobao Yang, Hua Bao*, Xiulin Ruan*, Electronic and phononic origins of BaSO4<\/sub> as an ultra-efficient radiative cooling paint pigment, Materials Today Physics<\/strong><\/em>, 24, 100658, 2022 (link<\/a>)<\/span><\/p>\n

[88] Han Wei, Hua Bao*<\/span><\/span>, Xiulin Ruan*<\/span><\/span>, Perspective: Predicting and optimizing thermal transport properties with machine learning methods, Energy and AI<\/em><\/strong>, 8, 100153, 2022 (link<\/a>)<\/span><\/p>\n

[87] Zhen Tong*<\/span><\/span>, Alessandro Pecchia, ChiYung Yam, Hua Bao, Traian Dumitric\u0103*<\/span><\/span>, Thomas Frauenheim*<\/span><\/span>, Significant Increase of Electron Thermal Conductivity in Dirac Semimetal Beryllonitrene by Doping Beyond Van Hove Singularity, Advanced Functional Materials,<\/strong><\/em> 32, 2111556, 2022 (link<\/a>)<\/span><\/p>\n

[86] Hao Wu#<\/sup>, Jiaxin Gu#<\/sup>, Zhongcheng Li#<\/sup>, Wenxiang Liu, Hua Bao, Huan Lin, Yanan Yue*<\/span><\/span>, Characterization of phonon thermal transport of Ti3<\/sub>C2<\/sub>Tx<\/sub> MXene thin film, Journal of Physics: Condensed Matter<\/strong><\/em>, 34, 155704, 2022 (link<\/a>)<\/span><\/p>\n

[85] Yufei Sheng#<\/sup>, Yue Hu#<\/sup>, Zheyong Fan, Hua Bao*<\/span><\/span>, Size effect and transient phonon transport mechanism in approach-to-equilibrium molecular dynamics simulations, Physical Review B<\/em><\/strong>, 105, 075301, 2022 (link<\/a>)<\/span><\/p>\n

[84] Ao Wang, Shouhang Li, Xinyu Zhang, Hua Bao*<\/span><\/span>, Roles of electrons on the thermal transport of 2D metallic MXenes, Physical Review Materials<\/em><\/strong>, 6, 014009, 2022 (link<\/a>)<\/span><\/p>\n

[83] Shuqian Zhang, Han Wei, Zhijian Zhang, Jianzhong Zhang, Hua Bao, Wang Zhang*, A bioinspired solar evaporator with a horizontal channel-like framework for efficient and stable high-salinity brine desalination, Nanoscale<\/em><\/strong>, 14, 6066-6074, 2022 (link<\/a>)<\/span><\/p>\n

[82] Pengli Li, Ao Wang, Junjie Fan, Qi Kang, Pingkai Jiang, Hua Bao*, Xingyi Huang*, Thermo\u2010Optically Designed Scalable Photonic Films with High Thermal Conductivity for Subambient and Above\u2010Ambient Radiative Cooling, Advanced Functional Materials<\/em><\/strong>, 32, 2109542, 2022 (link<\/a>)<\/span><\/p>\n

2021<\/em><\/strong><\/span><\/h3>\n

[81] Xiaokun Gu, Zheyong Fan, Hua Bao*<\/span><\/span>, Thermal conductivity prediction by atomistic simulation methods: Recent advances and detailed comparison, Journal of Applied Physics<\/em><\/strong>, 130, 210902, 2021 (link<\/a>)<\/span><\/p>\n

[80] Ying Lin, Qi Kang, Han Wei, Hua Bao, Pingkai Jiang, Yiu-Wing Mai, Xingyi Huang*, Spider Web-Inspired Graphene Skeleton-Based High Thermal Conductivity Phase Change Nanocomposites for Battery Thermal Management, Nano-micro letters<\/strong><\/em>, 13, 1-14, 2021 (link<\/a>)<\/span><\/p>\n

[79] Junyu Sun#<\/sup>, Jing Wang#<\/sup>*<\/span><\/span>, Taotao Guo, Hua Bao, Shuxin Bai*<\/span><\/span>, Daytime passive radiative cooling materials based on disordered media: A review, Solar Energy Materials and Solar Cells<\/em><\/strong>, 236, 111492, 2022 (link<\/a>)<\/span><\/p>\n

[78] <\/span>Xiao <\/span>Luo#<\/sup>, <\/span><\/span><\/span>Jincheng <\/span>Shi#<\/sup>, <\/span><\/span><\/span>Changying <\/span>Zhao, <\/span><\/span><\/span>Zhouyang <\/span>Luo*, <\/span><\/span><\/span>Xiaokun <\/span>Gu*, <\/span><\/span>Hua <\/span>Bao*, <\/span><\/span><\/span>The energy efficiency of interfacial solar desalination, <\/span>Applied Energy<\/strong><\/em>, 302, 117581, 2021 (<\/span>link<\/a>)<\/span><\/p>\n

[77] Jiaxuan Xu#<\/sup>, Yue Hu#<\/sup>, Xiulin Ruan, Xinyu Wang, Tianli Feng*<\/span><\/span>, Hua Bao*<\/span><\/span>, Nonequilibrium phonon transport induced by finite sizes: Effect of phonon-phonon coupling, Physical Review B<\/em><\/strong> 104, 104310, 2021 (link<\/a>)<\/span><\/p>\n

[76] Yisu <\/span>Xu, <\/span><\/span>Zhifu <\/span>Qi, <\/span><\/span><\/span>Zhouyang <\/span>Luo, <\/span><\/span>Zhen <\/span>Shen, <\/span><\/span>Chenxi <\/span>Li, <\/span><\/span><\/span>Guo <\/span>Chen, <\/span><\/span>Wenyi <\/span>Cai, <\/span><\/span>Hua <\/span>Bao, <\/span><\/span><\/span>Chang-Ching <\/span>Tu*<\/span><\/span>, Heat-concentrating solar steam generation and salt extraction based on water-repellent germanium nanoparticles-coated oxidized copper foams, Solar Energy Materials and Solar Cells<\/em><\/strong>, 230, 111191, 2021 (link<\/a>)<\/span><\/p>\n

[75] Dezhao Wang#<\/sup>, Han Wei#<\/sup>, Ying Lin, Pingkai Jiang, Hua Bao*, Xingyi Huang*, Achieving ultrahigh thermal conductivity in Ag\/MXene\/epoxy nanocomposites via filler-filler interface engineering, Composites Science and Technology<\/strong><\/em>, 213, 108953, 2021 (link<\/a>)<\/span><\/p>\n

[74] Huan Liu, Xin Qian, Hua Bao, Changying Zhao, Xiaokun Gu*, High-temperature phonon transport properties of SnSe from machine-learning interatomic potential, Journal of Physics: Condensed Matter<\/em><\/strong>, 33, 405401 2021 (link<\/a>)<\/span><\/p>\n

[73] Yue Hu, Shouhang Li, Hua Bao*<\/span>, First-principles based analysis of thermal transport in metallic nanostructures: Size effect and Wiedemann-Franz law, Physical Review B<\/em><\/strong>, 103, 104301, 2021 (link<\/a>)<\/span><\/p>\n

[72] Mengqi Liu, Changying Zhao*, Hua Bao, Transverse Kerker scattering governed by two nondegenerate electric dipoles and its application in arbitrary beam steering, Journal of Quantitative Spectroscopy and Radiative Transfer<\/strong><\/em>,\u00a0 262, 107514, 2021\u00a0(link<\/a>)<\/span><\/p>\n

[71] Jincheng <\/span>Shi, <\/span><\/span><\/span>Xiao <\/span>Luo, <\/span><\/span><\/span>Zhejun <\/span>Liu, <\/span><\/span><\/span>Junjie <\/span>Fan, <\/span><\/span>Zhouyang <\/span>Luo, <\/span><\/span><\/span>Changying <\/span>Zhao, <\/span><\/span><\/span>Xiaokun <\/span>Gu, <\/span><\/span><\/span>Hua <\/span>Bao*<\/span><\/span><\/span>, \u00a0Efficient and antifouling interfacial solar desalination guided by a transient salt capacitance model, Cell Reports Physical Science<\/strong><\/em>, 2, 100330, 2021 (link<\/a>)<\/span><\/p>\n

[70] Lan Dong, Xiangshui Wu, Yue Hu, Xiangfan Xu*, Hua Bao*, Suppressed thermal conductivity in polycrystalline gold nanofilm: effect of grain boundary and substrate, Chinese Physics Letters<\/strong><\/em>, 38, 27202, 2021 (link<\/a>)<\/span><\/p>\n

[69] Shouhang Li, <\/span>Xinyu Zhang<\/i>, <\/span>Hua Bao*,<\/i> \u00a0<\/span>Thermal transport by electrons and phonons in PdTe2<\/sub>: an ab initio<\/em> study, Physical Chemistry Chemical Physics, <\/strong><\/em>23, 5956-5962, 2021\u00a0(link<\/a>)<\/span><\/p>\n

2020<\/em><\/strong><\/span><\/h3>\n

[68] Shouhang Li, Zhen Tong, Xinyu Zhang, Hua Bao*, Thermal conductivity and Lorenz ratio of metals at intermediate temperatures with mode-level first-principles analysis, Physical Review B<\/em><\/strong>, 102, 174306, 2020 (link<\/a>)<\/span><\/p>\n

[67] Xingyi Huang*, Chunyi Zhi, Ying Lin, Hua Bao, Guangning Wu, Pingkai Jiang*, Yiu-Wing Mai*, Thermal conductivity of graphene-based polymer nanocomposites, Materials Science and Engineering: R: Reports,<\/strong><\/em> 142, 100577, 2020 (link<\/a>)<\/span><\/p>\n

[66] Shouhang Li#<\/sup>, Ao Wang#<\/sup>, Yue Hu, Xiaokun Gu, Zhen Tong, Hua Bao*, Anomalous thermal transport in metallic transition-metal nitrides originated from strong electron-phonon interactions, Materials Today Physics<\/strong><\/em>, 15, 100256, 2020 (link<\/a>)
\n<\/span><\/p>\n

[65]\u00a0 Chenyang Liu, Junjie, Fan, Hua, Bao*, Hydrophilic radiative cooler for direct water condensation in humid weather, Solar Energy Materials and Solar Cells<\/strong><\/em>, 216, 110700, 2020 (link<\/a>)<\/span><\/p>\n

[64] Han Wei, Hua Bao*, Xiulin Ruan*, Machine learning prediction of thermal transport in porous media with physics-based descriptors, International Journal of Heat and Mass Transfer<\/strong><\/em>, 160, 120176, 2020 (link<\/a>)<\/span><\/p>\n

[63] Xiaokun Gu#*, Shouhang Li#, Hua Bao*, Thermal conductivity of silicon at elevated temperature: role of four-phonon scattering and electronic heat conduction, International Journal of Heat and Mass Transfer<\/strong><\/em>, 160, 120165, 2020 (link<\/a>)<\/span><\/p>\n

[62] Chao Song#, Shouhang Li#, Hua Bao*, and Jaehyung Ju*, Design of thermal diodes using asymmetric thermal deformation of a Kirigami structure,\u00a0Materials & Design<\/em><\/strong>, 193, 108734, 2020 (link<\/a>)<\/span><\/p>\n

[61] Jiahao Yan#, Han Wei#, Han Xie, Xiaokun Gu, Hua Bao*,\u00a0Seeking for low thermal conductivity atomic configurations in SiGe alloys with Bayesian Optimization,\u00a0ES Energy & Environment<\/em><\/strong>, 8, 56-64, 2020 (link<\/a>)<\/span><\/p>\n

[60] Yue Hu#, Tianli Feng#, Xiaokun Gu, Zheyong Fan, Xuefeng Wang, Mark Lundstrom, Som S. Shretha, Hua Bao*,\u00a0Unification of nonequilibrium molecular dynamics and the mode-resolved phonon Boltzmann equation for thermal transport simulations,\u00a0Physical Review B<\/em><\/strong>, 101, 155308, 2020 (link)<\/a><\/span><\/p>\n

[59]Han Wei, Hua Bao*, Xiulin Ruan*,Genetic algorithm-driven discovery of unexpected thermal conductivity enhancement by disorder, Nano Energy<\/em><\/strong>, 71, 104619, 2020 (link)<\/a><\/span><\/p>\n

[58]Zhen Tong, Xiaolong Yang, Tianli Feng, Hua Bao*, Xiulin Ruan*, First-principles predictions of temperature-dependent infrared dielectric function of polar materials by including four-phonon scattering and phonon frequency shift, Physical Review B<\/em><\/strong>,101, 125416, 2020 (link)<\/a><\/span><\/p>\n

2019<\/em><\/strong><\/span><\/h3>\n

[57] Zhen Li, Shiyun Xiong*, Charles Sievers, Yue Hu, Zheyong Fan*, Ning Wei, Hua Bao*, Shunda Chen*, Davide Donadio*, and Tapio Ala-Nissila*, Influence of Thermostatting on Nonequilibrium Molecular Dynamics Simulations of Heat Conduction in Solids, Journal of Chemical Physics<\/em><\/strong>,151,234105, 2019 (link<\/a>)<\/span><\/p>\n

[56] Qingyuan Rong, Han Wei, Xingyi Huang, Hua Bao*, Predicting the effective thermal conductivity of composites from cross sections images using deep learning methods ,\u00a0Composites Science and Technology<\/em><\/strong>, 184, 107861, 2019 (link<\/a>)<\/span><\/p>\n

[55] Si Wu , Tingxian Li*, Zhen Tong, Jingwei Chao,Tianyao Zhai, Jiaxing Xu, Taisen Yan, Minqiang Wu, Zhenyuan Xu, Hua Bao, Tao Deng*, Ruzhu Wang*, High-Performance Thermally Conductive \u00a0Phase Change Composites by Large-Size Oriented Graphite Sheets for Scalable Thermal Energy Harvesting,\u00a0Advanced Materials<\/em><\/strong>, 31, 1905099, 2019 (link<\/a>)<\/span><\/p>\n

[54] Zhen Tong, Shouhang Li, Xiulin Ruan, Hua Bao*, Comprehensive first-principles analysis of phonon thermal conductivity and electron-phonon coupling in different metals,\u00a0Physical Review B<\/em><\/strong>, 100, 144306, 2019 (link<\/a>)<\/span><\/p>\n

[53] Jin Chen, Han Wei, Hua Bao, Pingkai Jiang, and Xingyi Huang*, \u00a0Millefeuille-Inspired Thermally Conductive Polymer Nanocomposites with Overlapping BN Nanosheets for Thermal Management Applications,\u00a0ACS Applied Materials & Interfaces<\/em><\/strong>, 11, 31402-3141, 2019 (link<\/a>)<\/span><\/p>\n

[52] Xiaokun Gu, Zheyong Fan, Hua Bao, C. Y. Zhao*, Revisiting phonon-phonon scattering in single-layer graphene,\u00a0Physical Review B<\/em><\/strong>, 100, 064306, 2019 (link<\/a>)<\/span><\/p>\n

[51]\u00a0(Invited Paper)<\/strong>\u00a0Shouhang Li, Zhen Tong, Hua Bao*,\u00a0Resolving different scattering effects on the thermal and electrical transport in doped SnSe,\u00a0Journal of Applied Physics,\u00a0<\/em><\/strong>126, 025111, 2019\u00a0(link) (Editor’s pick<\/strong>)<\/a><\/span><\/p>\n

[50] Han Xie, Jiahao Yan, Xiaokun Gu*, Hua Bao*,\u00a0A scattering rate model for accelerated evaluation of lattice thermal conductivity bypassing anharmonic force constants, Journal of Applied Physics,<\/em><\/strong>\u00a0125, 205104, 2019 (link<\/a>) (Editor’s pick<\/strong>)<\/span><\/p>\n

[49]Hyeonu Heo \u00a0Shouhang Li \u00a0Hua Bao*, and Jaehyung Ju*, A Passive Thermal Switch with Kirigami\u2010Inspired Mesostructures,\u00a0Advanced Engineering Materials<\/em><\/strong>, 21, 1900225, 2019 (link<\/a>)<\/span><\/p>\n

[48]\u00a0Saeid Zahiri, Zhan Xu, Yue Hu, Hua Bao*, and YongxingShen*, A semi-Lagrangian method to solve the nongray phonon Boltzmann transport equation, International Journal of Heat and Mass Transfer,<\/em><\/strong>\u00a0138, 267-276, 2019 (link<\/a>)<\/span><\/p>\n

[47]\u00a0Peng Tao*, \u00a0Chao Chang, \u00a0Zhen Tong, \u00a0Hua Bao, \u00a0Chengyi Song, \u00a0Jianbo Wu, \u00a0Wen Shang \u00a0and \u00a0Tao Deng*,\u00a0Magnetically-accelerated large-capacity solar-thermal energy storage within high-temperature phase-change materials,\u00a0Energy Environ. Sci.\u00a0<\/em><\/strong>12, 1613-1621, 2019 (link)<\/a><\/span><\/p>\n

[46] Chenyang Liu, Yizhou Wu, Boxiang Wang, C. Y. Zhao, Hua Bao*,\u00a0Effect of atmospheric water vapor on radiative cooling performance of different surfaces,\u00a0Solar Energy<\/em><\/strong>, 183, 218-225, 2019 (link<\/a>)<\/span><\/p>\n

[45] Jianshu Gao, Chuizhou Meng, Danmei Xie*, Chenyang Liu, Hua Bao*, Bo Yang, Maodong Li, Yanan Yue*,\u00a0Temperature dependent thermal transport in graphene paper above room temperature,\u00a0Applied Thermal Engineering<\/em><\/strong>, 150, 1252-1259, 2019 (link<\/a>)<\/span><\/p>\n

[44]<\/span>\u00a0Tao Ouyang*,\u00a0Qingyi Liu,\u00a0Mingxing Chen,\u00a0Chao Tang,\u00a0Jin Li,\u00a0Chunxiao Zhang,\u00a0Chaoyu He,\u00a0Hua Bao*,\u00a0Jianxin Zhong\u00a0and\u00a0Ming Hu*,\u00a0Doping Induced Abnormal Contraction and Significant Reduction of Lattice Thermal Conductivity of Open Framework Si24,\u00a0<\/sub>ES Energy & Environment<\/em><\/strong>,\u00a03<\/strong>, 88\u201395, 2019 (link<\/a>)<\/span><\/p>\n

[43] Xingyan Zhao, Jiahao Yan, Hua Bao, and Yaping Dan,\u00a0Single silicon nanowires as inherent heaters and thermometers for thermal conductivity measurements,\u00a0AIP Advances<\/em><\/strong>, 9, 015107 (link<\/a>)<\/span><\/p>\n

2018<\/em><\/strong><\/span><\/h3>\n

[42]\u00a0(Invited Review)<\/strong>\u00a0Hua Bao*, Jie Chen*, Xiaokun Gu*, Bingyang Cao*, A Review of Simulation Methods for Micro\/Nanoscale Heat Conduction,\u00a0ES Energy & Environment<\/em><\/strong>, 1, 16-55,\u00a02018\u00a0(link<\/a>)<\/span><\/p>\n

[41] Cheng Shao, Qingyuan Rong, Nianbei Li, and Hua Bao*,\u00a0Understanding the mechanism of diffuse phonon scattering at disordered surfaces by atomistic wave-packet investigation, Physical Review B<\/strong><\/em>, 98, 155418, 2018 (link<\/a>)<\/span><\/p>\n

[40] Han Wei, Shuaishuai Zhao, Qingyuan Rong, and Hua Bao*,\u00a0Predicting the effective thermal conductivities of composite materials and porous media by machine learning methods, International Journal of Heat and Mass Transfer,<\/em><\/strong>\u00a0127, 908-916, 2018 (link<\/a>)<\/span><\/p>\n

[39] Shouhang Li#<\/sup>, Xiaoxiang Yu#<\/sup>, Hua Bao*, and Nuo Yang*, High Thermal Conductivity of Bulk Epoxy Resin by Bottom-Up Parallel-Linking and Strain: A Molecular Dynamics Study, Journal of Physical Chemistry C<\/em><\/strong>, 22, 13140\u201313147, 2018 (link<\/a>)<\/span><\/p>\n

[38]\u00a0(Invited\u00a0Paper)<\/strong>\u00a0Saeid Zahiri, Jiaqi Zuo, Yongxing Shen*, Hua Bao*,\u00a0Numerical investigation of ballistic-diffusive heat transfer through a constriction with the Boltzmann transport equation,\u00a0Applied Thermal Engineering<\/strong><\/em>, 141,\u00a0126\u2013133, 2018 (link<\/a>)<\/span><\/span><\/p>\n

[37] Xiaoyuan Ying, Fangming Ye, Ruitao Liu, and Hua Bao*, Design and optimization of thermoelectric cooling system under natural convection condition, Journal of Thermal Science and Engineering Applications, <\/em><\/strong>10, 051008, 2018 (link<\/a>)<\/span><\/p>\n

[36] Zhen Tong, Linhua Liu, Liangsheng Li* and Hua Bao*, Temperature-dependent infrared optical properties of 3C-, 4H- and 6H-SiC,\u00a0Physica B<\/em><\/strong>, 537, 194-201, 2018\u00a0(link<\/a>)<\/span><\/p>\n

[35] Xing Fang, C. Y. Zhao* and Hua Bao, Design and analysis of Salisbury screens and Jaumann absorbers for solar radiation absorption,\u00a0Frontiers in Energy<\/em><\/strong>, 12,158-168, 2018 (link<\/a>)<\/span><\/p>\n

[34] Zhen Tong and Hua Bao*, Decompose the electron and phonon thermal transport of intermetallic compounds NiAl and Ni3<\/sub>Al by first-principles calculations, International Journal of Heat and Mass Transfer<\/strong><\/em>, 117, 972-977, 2018 (link<\/a>)<\/span><\/p>\n

[33] Shuaishuai Zhao, Cheng Shao, Saeid Zahiri, Changying Zhao, Hua Bao*, Thermal Transport in Nanoporous Yttria-Stabilized Zirconia by Molecular Dynamics Simulation,\u00a0Journal of Shanghai Jiao Tong University (JI special issue)<\/em>\u00a0<\/strong>\u4e0a\u6d77\u4ea4\u901a\u5927\u5b66\u5b66\u62a5\u5bc6\u897f\u6839\u5b66\u9662\u7279\u520a, 23<\/b>, 38\u201344, 2018. (link<\/a>)<\/span><\/p>\n

2017<\/em><\/strong><\/span><\/h3>\n

[32] Zhongyong Wang, Zhen Tong, Qinxian Ye, Hang Hu, Xiao Nie, Chen Yan, Wen Shang, Chengyi Song, Jianbo Wu, Jun Wang, Hua Bao*, Peng Tao*, Tao Deng*, Dynamic tuning of optical absorbers for accelerated solar-thermal energy storage,\u00a0Nature Communications<\/em><\/strong>,\u00a08, 1478,\u00a02017\u00a0(link<\/a>)<\/span><\/p>\n

(Click here to see the News<\/a>, \u8bf7\u70b9\u51fb\u6b64\u5904<\/a>\u67e5\u770b\u76f8\u5173\u62a5\u5bfc\uff09<\/span><\/p>\n

[31] Cheng Shao, Qingyuan Rong, Ming Hu, and Hua Bao*, <\/span>Probing phonon-surface interaction by wave-packet simulation: Effect of roughness and morphology, <\/span>Journal of Applied Physics, <\/em><\/strong>122, 155104, 2017 (link<\/a>)<\/span><\/span><\/p>\n

[30] Han Xie, Xiaokun Gu, Hua Bao*, Effect of the accuracy of interatomic force constants on the prediction of lattice thermal conductivity,\u00a0Computational Materials Science<\/em><\/strong>, 138, 368-376, 2017 (link<\/a>) (Editor’s Choice<\/strong>)<\/span><\/p>\n

[29] Hua Bao*, Chen Yan, Boxiang Wang, Xing Fang, C. Y. Zhao, Xiulin Ruan, Double-layer nanoparticle-based coatings for efficient terrestrial radiative cooling,\u00a0Solar Energy Materials and Solar Cells<\/em><\/strong>, 168, 78-84, 2017 (link<\/a>)<\/span><\/p>\n

(China Patent, \u4e2d\u56fd\u53d1\u660e\u4e13\u5229\uff0cZL201510846914.4, \u4e00\u79cd\u8f90\u5c04\u5236\u51b7\u53cc\u5c42\u7eb3\u7c73\u6d82\u5c42\u53ca\u5176\u5236\u5907\u65b9\u6cd5\uff09<\/span><\/p>\n

[28]\u00a0(Topical Review)<\/strong>\u00a0Cheng Shao, Xiaoxiang Yu, Nuo Yang, Yanan Yue, and Hua Bao*, A review of thermal transport in low-dimensional materials under external perturbation: effect of strain, substrate, and clustering,\u00a0Nanoscale and Microscale Thermophysical Engineering<\/em><\/strong>, 21, 1-36, 2017 (link<\/a>)<\/span><\/p>\n

[27] Qingyuan Rong, Cheng Shao, and Hua Bao*, Molecular dynamics study of the interfacial thermal conductance of multi-walled carbon nanotubes and van der Waals force induced deformation, Journal of Applied Physics<\/em><\/strong>, 121, 054302, 2017 (link<\/a>)<\/span><\/p>\n

2016<\/em><\/strong><\/span><\/h3>\n

[26] Saeid Zahiri, Cheng Shao, Yongxing Shen*, Hua Bao*, Collocation Meshfree Method to Solve the Gray Phonon Boltzmann Transport Equation,\u00a0Numerical Heat Transfer, Part B: Fundamentals<\/em><\/strong>, 70, 459\u2013471, 2016. (link<\/a>)<\/span><\/p>\n

[25] Cheng Shao and Hua Bao*, Thermal transport in bismuth telluride quintuple layer: mode-resolved phonon properties and substrate effects,\u00a0Scientific Reports,<\/em><\/strong>\u00a06, 27492, 2016 (link<\/a>)<\/span><\/p>\n

[24] Zhen Tong, Meng Liu, and Hua Bao*, A numerical investigation on the heat conduction in high filler loading particulate composites, International Journal of Heat and Mass Transfer, <\/em><\/strong>100, 355-361, 2016 (PDF<\/a>)<\/span><\/p>\n

[23]\u00a0A.K. Vallabhaneni, D. Singh, H. Bao, J.Y. Murthy, and X.L. Ruan*, Reliability of Raman measurements of thermal conductivity of single-layer graphene due to selective electron-phonon coupling, Physical Review B<\/strong><\/em>, 93, 125432, 2016 (link<\/a>)<\/span><\/p>\n

[22] Han Xie, Tao Ouyang, \u00c9ric Germaneau, Guangzhao Qin, Ming Hu* and Hua Bao*, Large Tunability of Lattice Thermal Conductivity of Monolayer Silicene via Mechanical Strain, Physical Review B<\/strong><\/em>, 93, 075404, 2016 (link<\/a>)<\/span><\/p>\n

[21] Hua Bao* and Xiulin Ruan*, Absorption Spectra and Electron-Vibration Coupling of Ti:sapphire from First-Principles,\u00a0ASME Journal of Heat Transfer<\/em><\/strong>, 138, 042702, 2016 (link<\/a>)<\/span><\/p>\n

2015<\/em><\/strong><\/span><\/h3>\n

[20] Jingchao Zhang, Yang Hong, Zhen Tong, Zhihuai Xiao*, Hua Bao and Yanan Yue*, Molecular Dynamics Study of Interfacial Thermal Transport between Silicene and Substrate, Physical Chemistry Chemical Physics, 17, 23704, 2015 (link<\/a>) (Selected as the backcover article of the issue.)<\/span><\/p>\n

[19] Xiaoliang Zhang, Hua Bao*, Ming Hu*, “Bilateral Substrate Effect on the Thermal Conductivity of Two-dimensional Silicon “,\u00a0Nanoscale<\/em><\/strong>, 7, 6014-6022, 2015 (link<\/a>).<\/span><\/p>\n

[18] Cheng Shao and Hua Bao*, “A Molecular Dynamics Investigation of Heat Transfer across a Disordered Thin Film”, International Journal of Heat and Mass Transfer<\/strong><\/em>, 85, 33-40, 2015 (link<\/a>)<\/span><\/p>\n

[17] X. Fang, M. Lou, H. Bao*, C. Zhao*, “Thin films with disordered nanohole patterns for solar radiation absorbers”, \u00a0<\/em><\/strong>Journal of Quantitative Spectroscopy and Radiative Transfer<\/span><\/em><\/strong>, 158, 145\u2013153, 2015 (link<\/a>)<\/span><\/p>\n

[16] Hua Bao*, Anurag Kumar, Yuannan Cai, Yuzhong Ji, Timothy S. Fisher, Xiulin Ruan*,”Optical Properties of Thin Graphitic Nanopetal Arrays”, \u00a0<\/em><\/strong>Journal of Quantitative Spectroscopy and Radiative Transfer<\/span><\/em><\/strong>, 158, 84-90, 2015\u00a0(link<\/a>)<\/span><\/p>\n

2013-2014<\/em><\/strong><\/span><\/h3>\n

[15] Han Xie, Ming Hu*, Hua Bao*, “Thermal conductivity of silicene from first-principles”,\u00a0Applied Physics Letters<\/strong><\/em> 104, 131906, 2014 (link<\/a>)<\/span><\/p>\n

[14] Xiaoliang Zhang, Han Xie, Ming Hu*, Hua Bao*, Shengying Yue, Guangzhao Qin,and Gang Su, “Thermal conductivity of silicene calculated using an optimized Stillinger-Weber potential”, Physical Review B<\/strong><\/em>, 89, 054310, 2014\u00a0(link<\/a>)<\/span><\/p>\n

[13] Hua Bao*, Cheng Shao, Shirui Luo, and Ming Hu*, “Enhancement of interfacial thermal transport by carbon nanotube-graphene junction”, Journal of Applied Physics<\/em><\/strong>, 115, 053524, 2014 (link<\/a>)<\/span><\/p>\n

[12] X. Fang, CY Zhao*, H. Bao\u00a0“Radiative behaviors of crystalline silicon nanowire and nanohole arrays for photovoltaic applications”, \u00a0<\/em><\/strong>Journal of Quantitative Spectroscopy and Radiative Transfer<\/span><\/em><\/strong>,133, 579-588, 2014 (link<\/a>)<\/span><\/p>\n

[11] Hua Bao*, “Prediction of Lattice Thermal Conductivity of Solid Argon from Anharmonic Lattice Dynamics Method”,\u00a0Acta Physica Sinica\u00a0<\/strong><\/em>(\u7269\u7406\u5b66\u62a5, in Chinese), 62, 186302, 2013 (link<\/a>)<\/span><\/p>\n

[10]\u00a0H. Bao, B. Duvvuri, M.H. Lou, and X.L. Ruan*, “Effects of Randomness and Inclination on the Optical Properties of Multi-walled Carbon Nanotube Arrays”,\u00a0\u00a0<\/em><\/strong>Journal of Quantitative Spectroscopy and Radiative Transfer<\/span><\/em><\/strong>, 132, 22-27, 2014 (link<\/a>)<\/span><\/p>\n

Before 2012<\/em><\/strong><\/span><\/h3>\n

[9] Hua Bao, Weixia Zhang, Liangliang Chen, Haoxiang Huang, Chen Yang, and Xiulin Ruan*, “An Investigation of the Optical Properties of Disordered Silicon Nanowire Mats”, Journal of Applied Physics<\/strong>, <\/em>112<\/strong>,\u00a0<\/em>124301,2012 (link<\/a>).<\/em><\/span><\/p>\n

[8]\u00a0H. Bao*, B. Qiu, Y. Zhang, and X.L. Ruan*, “A first-principles molecular dynamics approach for predicting optical phonon lifetimes and far-infrared reflectance of polar materials”,\u00a0<\/em><\/strong>Journal of Quantitative Spectroscopy and Radiative Transfer<\/span><\/em><\/strong>, 113, 1683-1688, 2012 (link<\/a>)<\/span><\/p>\n

[7] B. Qiu, H. Bao, G.Q. Zhang, Y. Wu and X.L. Ruan*, Molecular Dynamics Simulations of Lattice Thermal Conductivity and Spectral Phonon Mean Free Path of PbTe: Bulk and Nanostructures, Computational Materials Science<\/em><\/strong>, 53, 278-285, 2012 (link<\/a>)<\/span><\/p>\n

[6] L.L. Chen, H. Bao, T.Z. Tan, O.L. Prezhdo, and X.L. Ruan*, Shape and Temperature Dependence of Hot Carrier Relaxation Dynamics in Spherical and Elongated CdSe Quantum Dots,\u00a0Journal of Physical Chemistry C<\/em><\/strong> 115, 11400\u201311406, 2011 (link<\/a>).<\/span><\/p>\n

[5]\u00a0<\/strong>Hua Bao and Xiulin Ruan*, Enhanced optical absorption in disordered vertical silicon nanowire arrays for photovoltaic applications,\u00a0Optics Letters<\/strong><\/em>, 35, 3378, 2010 (link<\/a>).<\/span><\/p>\n

[4]\u00a0Hua Bao,<\/strong>\u00a0Xiulin Ruan*, and Timothy S. Fisher, Optical properties of ordered vertical arrays of multi-walled carbon nanotubes from FDTD simulations,\u00a0Optics Express<\/strong><\/em>,\u00a018, 6347, 2010 (link<\/a>)<\/span><\/p>\n

[3]\u00a0<\/strong>H. Bao and X. Ruan*, Ab initio calculations of thermal radiative properties: the semiconductor GaAs,\u00a0International Journal of Heat and Mass Transfer,<\/strong> <\/em>53, 1308-1312, 2010 (link<\/a>)<\/span><\/p>\n

[2]\u00a0<\/strong>Hua Bao, Bradley F. Habenicht, Oleg V. Prezhdo, and Xiulin Ruan*, Temperature dependence of hot carrier relaxation in a PbSe nanocrystal: an ab initio study,\u00a0Physical Review B<\/strong><\/em>\u00a079,235306-1-7, 2009 (link<\/a>)<\/span><\/p>\n

[1]\u00a0<\/strong>H. Bao, X.L. Ruan*, and M. Kaviany, Theory of the broadening of vibrational spectra induced by lowered symmetry in yttria nanostructures,\u00a0Physical Review B<\/strong><\/em>\u00a078, 125417-1-7, 2008 (selected as Virtual Journal of Nanoscale Science & Technology, volume 18, issue 14) (link<\/a>)<\/span><\/p>\n","protected":false},"excerpt":{"rendered":"

Journal Papers: (* denotes the corresponding author) Reviews: [88] (Review) Han Wei, Hua Bao*, Xiulin Ruan*, Perspective: Predicting and optimizing thermal transport properties with machine learning methods, Energy and AI, 8, 100153, 2022 (link) [81] (Review) Xiaokun Gu, Zheyong Fan, Hua Bao*, Thermal conductivity prediction by atomistic simulation methods: Recent advances and detailed comparison, Journal […]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"site-sidebar-layout":"default","site-content-layout":"default","ast-site-content-layout":"default","site-content-style":"default","site-sidebar-style":"default","ast-global-header-display":"","ast-banner-title-visibility":"","ast-main-header-display":"","ast-hfb-above-header-display":"","ast-hfb-below-header-display":"","ast-hfb-mobile-header-display":"","site-post-title":"disabled","ast-breadcrumbs-content":"","ast-featured-img":"","footer-sml-layout":"","theme-transparent-header-meta":"default","adv-header-id-meta":"","stick-header-meta":"","header-above-stick-meta":"","header-main-stick-meta":"","header-below-stick-meta":"","astra-migrate-meta-layouts":"set","ast-page-background-enabled":"default","ast-page-background-meta":{"desktop":{"background-color":"","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""},"tablet":{"background-color":"","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""},"mobile":{"background-color":"","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""}},"ast-content-background-meta":{"desktop":{"background-color":"var(--ast-global-color-5)","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""},"tablet":{"background-color":"var(--ast-global-color-5)","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""},"mobile":{"background-color":"var(--ast-global-color-5)","background-image":"","background-repeat":"repeat","background-position":"center center","background-size":"auto","background-attachment":"scroll","background-type":"","background-media":"","overlay-type":"","overlay-color":"","overlay-opacity":"","overlay-gradient":""}},"footnotes":""},"class_list":["post-6","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/sites.gc.sjtu.edu.cn\/hua-bao\/wp-json\/wp\/v2\/pages\/6","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/sites.gc.sjtu.edu.cn\/hua-bao\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/sites.gc.sjtu.edu.cn\/hua-bao\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/sites.gc.sjtu.edu.cn\/hua-bao\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/sites.gc.sjtu.edu.cn\/hua-bao\/wp-json\/wp\/v2\/comments?post=6"}],"version-history":[{"count":66,"href":"https:\/\/sites.gc.sjtu.edu.cn\/hua-bao\/wp-json\/wp\/v2\/pages\/6\/revisions"}],"predecessor-version":[{"id":562,"href":"https:\/\/sites.gc.sjtu.edu.cn\/hua-bao\/wp-json\/wp\/v2\/pages\/6\/revisions\/562"}],"wp:attachment":[{"href":"https:\/\/sites.gc.sjtu.edu.cn\/hua-bao\/wp-json\/wp\/v2\/media?parent=6"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}