1. Xin Qian, and Ronggui Yang, Temperature effect on the phonon dispersion stability of zirconium by machine learning driven atomistic simulations, Physical Review B 98, Vol. 98, p.224108, 2018, Web Link.
2. Puqing Jiang, Xin Qian, Ronggui Yang, and Lucas Lindsay, Anisotropic Thermal Transport in Bulk Hexagonal Boron Nitride, Physical Review Materials, Vol 2, Art # 064005, 2018, Web Link.
3. Puqing Jiang, Xin Qian, Xiaobo Li, and Ronggui Yang, Three-dimensional anisotropic thermal conductivity tensor of single crystalline β-Ga2O3, Applied Physics Letters, Vol. 113, 232105, 2018, Web Link.
4. Xiaokun Gu, Yujie Wei, Xiaobo Yin, Baowen Li, and Ronggui Yang, Colloquium: Phononic thermal properties of two-dimensional materials, Review of Modern Physics, Vol. 90, p.041002, 2018, Web Link.
5.Puqing Jiang, Xin Qian, and Ronggui Yang, Tutorial: Time-domain thermoreflectance (TDTR) for thermal property characterization of bulk and thin film materials, Journal of Applied Physics, Vol.124, 161103, 2018, Web Link.
6. Rongfu Wen, Xuehu Ma, Yung-Cheng Lee, Ronggui Yang, Liquid-Vapor Phase-Change Heat Transfer on Functionalized Nanowired Surfaces and Beyond, Joule, Vol.2, pp.2107-2347, 2018, Web Link.
7. Rongfu Wen, Shanshan Xu, Dongliang Zhao, Lixin Yang, Xuehu Ma, Wei Liu, Yung-Cheng Lee, Ronggui Yang, Sustaining enhanced condensation on hierarchical mesh-covered surfaces, National Science Review, Vol. 5, pp. 878-887, 2018, Web Link.
8.Kai Zhang, Dongliang Zhao, Xiaobo Yin, Ronggui Yang, Gang Tan, Energy saving and economic analysis of a new hybrid radiative cooling system for single-family houses in the USA, Applied Energy, Vol. 224, pp. 371-381, 2018, Web Link.
9.Xing Lu, Dongliang Zhao, Ting Ma, Qiuwang Wang, Jintu Fan, Ronggui Yang, Thermal resistance matching for thermoelectric cooling systems, Energy Conversion and Management, Vol. 169, 186-193, 2018,Web Link.
10. Rongfu Wen, Shanshan Xu, Yung-Cheng Lee, Ronggui Yang, Capillary-Driven Liquid Film Boiling Heat Transfer on Hybrid Mesh Wicking Structures, Nano Energy, Vol.51, pp.373-382, 2018,Web Link.
11. Xinpeng Zhao, Congliang Huang, Qingkun Liu, Ivan I. Smalyukh, and Ronggui Yang*, Thermal conductivity model for nanofiber networks, Journal of Applied Physics, Vol 123, 085103, 2018, Web Link.
12. Xin Qian, Puqing Jiang, Peng Yu, Xiaokun Gu, Zheng Liu, Ronggui Yang, Anisotropic thermal transport in van der Waals layered alloys WSe2 (1-x)Te2x, Applied Physics Letters, Vol.112, no. 24: 241901,2018, Web Link.
13. Zhenqian Pang, Xiaokun Gu, Yujie Wei, Ronggui Yang, Electronic band structure of carbon honeycombs, Materials Today Physics, Vol.5, 72-77, 2018, Web Link.
14. Fei Zhao, Xingyi Zhou, Ye Shi, Xin Qian, Megan Alexander, Xinpeng Zhao, Samantha Mendez, Ronggui Yang, Liangti Qu, Guihua Yu, Highly efficient solar vapour generation via hierarchically nanostructured gels, Nature Nanotechnology, Vol. 13, pp. 489-495, 2018,Web Link.
15. Qingkun Liu, Allister W Frazier, Xinpeng Zhao, A Joshua, Andrew J Hess, Ronggui Yang, Ivan I. Smalyukh, Flexible transparent aerogels as window retrofitting films and optical elements with tunable birefringence,Nano Energy, Vol.48, pp.266-274, 2018, Web Link.
16. Dongliang Zhao, Xing Lu, Tianzhu Fan, Yuen Shing Wu, Lun Lou, Qiuwang Wang, Jintu Fan, Ronggui Yang, Personal thermal management using portable thermoelectrics for potential building energy saving, Applied Energy, Vol. 218, pp.282-291, 2018, Web Link.
17. Tian Li, Jianwei Song, Xinpeng Zhao, Zhi Yang, Glenn Pastel, Shaomao Xu, Chao Jia, Jiaqi Dai, Chaoji Chen, Amy Gong, Feng Jiang, Yonggang Yao, Tianzhu Fan, Bao Yang, Lars Wågberg, Ronggui Yang, Liangbing Hu, Anisotropic, lightweight, strong, and super thermally insulating nanowood with naturally aligned nanocellulose, Science Advances,Vol. 3,Art # eaar3724, 2018, Web Link.
18. Tian Li, He Liu, Xinpeng Zhao, Guang Chen, Jiaqi Dai, Glenn Pastel, Chao Jia, Chaoji Chen, Emily Hitz, Das Siddhartha, Ronggui Yang, Liangbing Hu, Scalable and Highly Efficient Mesoporous Wood‐Based Solar Steam Generation Device: Localized Heat, Rapid Water Transport, Advanced Functional Materials, Vol. 28, 1707134, 2018, Web Link.
19. Xinpeng Zhao, Congliang Huang, Qingkun Liu, Ivan I. Smalyukh, Ronggui Yang,Thermal conductivity model for nanofiber networks,Journal of Applied Physics,Vol. 123, Art # 085103(10 pages), 2018, Web Link.
20. Congliang Huang, Xinpeng Zhao, Keith Regner, and Ronggui Yang, Thermal conductivity model for nanoporous thin films, Physica E: Low-dimensional Systems and Nanostructures, Vol. 97, pp. 277-281, 2018, Web Link.
21. Yilin Wang, Lisha Xu, Zhi Yang, Hua Xie, Puqing Jiang, Jiaqi Dai, Wei Luo, Yonggang Yao, Emily Hitz, Ronggui Yang, Bao Yang, and Liangbing Hu, High temperature thermal management with boron nitride nanosheets, Nanoscale, Vol. 10, pp. 167-173, 2018,Web Link.
22.Feng Jiang, He Liu, Yiju Li, Yudi Kuang, Xu Xu, Chaoji Chen, Hao Huang, Chao Jia, Xinpeng Zhao, Emily Hitz, Yubing Zhou, Ronggui Yang, Lifeng Cui, and Liangbing Hu, Lightweight, Mesoporous, and Highly Absorptive All-Nanofiber Aerogel for Efficient Solar Steam Generation, ACS Applied Materials and Interfaces, Vol. 10, pp. 1104-1112, 2018,Web Link.
23. He Liu, Chaoji Chen, Guang Chen, Yudi Kuang, Xinpeng Zhao, Jianwei Song, Chao Jia, Xu Xu, Emily Hitz, Hua Xie, Sha Wang, Feng Jiang, Tian Li, Yiju Li, Amy Gong, Ronggui Yang, Siddhartha Das, Liangbing Hu, High-Performance Solar Steam Device with Layered Channels: Artificial Tree with a Reversed Design, Advanced Energy Materials, Vol.8, Article # 1701616, 2018, Web Link.
24. Puqing Jiang, Xin Qian, Ronggui Yangm A new elliptical-beam method based on time-domain thermoreflectance (TDTR) to measure the in-plane anisotropic thermal conductivity and its comparison with the beam-offset method, Review of Scientific Instruments, Vol. 89, Art # 094902, 2018, Web Link.
25.Rongfu Wen, Shanshan Xu, Xuehu Ma, Yung-Cheng Lee, and Ronggui Yang, Three-Dimensional Superhydrophobic Nanowire Networks for Enhancing Condensation Heat Transfer, Joule, Vol. 2, pp. 269-279. 2018,Web Link.
2017年及以前
2023年
2018年
2019年
2020年
2021年
2022年
Time-domain thermoreflectance (TDTR) data analysis using phonon hydrodynamic model
Enhanced electromagnetic shielding and thermal conductive properties of polyolefin composites with a Ti3C2Tx MXene/graphene framework connected by a hydrogen-bonded interface
Xue Tan#, Te-Huan Liu#, Wenjiang Zhou, Qilong Yuan, Junfeng Ying, Qingwei Yan, Le Lv, Lu Chen, Xiangze Wang, Shiyu Du, Yan-Jun Wan*, Rong Sun, Kazuhito Nishimura, Jinhong Yu, Nan Jiang, Wen Dai*, Cheng-Te Lin*
Effects of electron-phonon intervalley scattering and band non-parabolicity on electron transport properties of high-temperature phase SnSe: An ab initio study
Significant suppression of phonon transport in polar semiconductors owing to electron-phonon-induced dipole coupling: An effect of breaking centrosymmetry
A new elliptical-beam method based on time-domain thermoreflectance (TDTR) to measure the in-plane anisotropic thermal conductivity and its comparison with the beam-offset method