冯杜东

冯杜东，入选国家高层次青年人才。2014年本科毕业于浙江大学能源与环境系统工程，2016年硕士毕业于美国卡耐基梅隆大学机械工程学系，2017年加入SF Motors(赛力斯北美研发中心)担任机械工程师，2021年博士毕业于美国佐治亚理工学院机械工程学系，此后于美国普渡大学从事博士后研究。2025年5月加入东南大学。

主要研究领域包括微纳尺度光电热转换、器件热管理、新型辐射能量转换器、辐射制冷涂料、多尺度多物理场数值计算以及AI4Engineering。已发表高水平SCI论文20余篇，其中以第一作者/通讯作者发表有10余篇，包括Advanced Materials、ACS Nano, Nano Letters、Nano Energy、Physical Review B等，曾多次受邀参加国际会议，其个人的会议展示也获得2019年美国机械工程师协会（ASME）的国际机械工程会议（IMECE）最佳理论工作奖，也曾多次主持行业内重要国际会议，任ASME K-8和K-9委员会成员。曾多次荣获会议旅行资助奖(佐治亚理工学院，普渡大学，欧洲材料研究协会等) ，普渡大学博士后特别认可奖，以及2021年国家优秀自费留学生。

课题组现开放多个博士（2-3名）与硕士研究生（2-3名）招生名额，并长期招聘博士后及科研助理。欢迎具有工程热物理、纳米光学、固体物理以及人工智能等相关理工科背景的同学加入。我们期待有志有识的同道年轻人，一起探索创造！

1.    Feng, D., Witty, A. S., Birnbaum, F. I., Gonzalez, O. G. R., Felicelli, A., Lee, W. J., Barber, E., & Ruan, X. (2025). Self‐Stratifying Colored Radiative Cooling Paints Through Narrow‐Band Color Preservation Scheme. Advanced Materials, e04382.

2.    Feng, D., & Ruan, X. (2025). Concentrated Near-Field Thermoradiative Device Approaching Solar Cell Performance at Nighttime. ACS nano, 19(18), 17357-17364.

3.     Barber, E., Feng, D., Fang, Z., Carne, D., Gonzalez, O. R., Lee, W. J., Navdeep Vansal., N., Raykova, K., & Ruan, X. (2025). Efficient, Hydrophobic, and Weather-Resistant Radiative Cooling Paints with Silicone-Based Binders. ACS Applied Optical Materials, 3(5), 1137-1144.

4.    Carne, D., Peoples, J., Guo, Z., Feng, D., Han, Z., Liu, X., & Ruan, X. (2025). FOS: A fully integrated open-source program for Fast Optical Spectrum calculations of nanoparticle media. Computer Physics Communications, 307, 109393.

5.   Feng, D., Yang, X., Han, Z. and Ruan, X., (2024). Near-field radiation in BAs and BSb dominated by four-phonon scattering. Physical Review B, 109(8), p.L081409.

6.   Felicelli, A., Wang, J., Feng, D., Forti, E., El Awad Azrak, S., Peoples, J., Youngblood, J., Chiu, G. and Ruan, X., (2024). Efficient radiative cooling of low-cost BaSO4 paint-paper dual-layer thin films. Nanophotonics, 13(5), pp.639-648.

7.   Guo, Z., Han, Z., Feng, D., Lin, G., & Ruan, X. (2024). Sampling-accelerated prediction of phonon scattering rates for converged thermal conductivity and radiative properties. npj Computational Materials, 10(1), p.31.

8. Li, L., Yu, K., Feng, D., Yang, Z., Zhang, K., Liu, Y., & Wu, X. (2023). High-performance near-field thermophotovoltaics based on a CaCO3/graphene/InSb heterostructure. Physical Review Applied, 20(6), pp. 064015.

9.  Feng, D., Yang, X., and Ruan, X., (2023). Phonon scattering engineered unconventional thermal radiation at the nanoscale. Nano Letters Vol. 23, p. 10044-10050.

10. Guo, Z., Roy Chowdhury, P., Han, Z., Sun, Y., Feng, D., Lin, G., & Ruan, X. (2023). Fast and accurate machine learning prediction of phonon scattering rates and lattice thermal conductivity. npj Computational Materials, Vol. 9, pp. 95.

11. Feng, D., Ruan, X., Yee, S. K., & Zhang, Z. M. (2022). Thermoradiative device enabled by hyperbolic phonon polaritons at nanoscales. Nano Energy, Vol. 103, pp. 107831

12. Feng, D., Yee, S. K., & Zhang, Z. M. (2022). Geometric and doping effects on radiative recombination in thin-film near-field energy converters. AIP Advances, Vol. 12, pp. 095006

13. Feng, D., Yee, S. K., & Zhang, Z. M. (2021). Improved performance of a near-field thermophotovoltaic system by a back gapped reflector. Solar Energy Materials and Solar Cells, Vol. 237, pp. 111562

14. Feng, D., Yee, S. K., & Zhang, Z. M. (2021). Near-field photonic thermal diode based on hBN and InSb films. Applied Physics Letters, Vol. 119, pp.181111.

15. Feng, D., Tervo, E. J., Vasileska, D., Yee, S. K., Rohatgi, A., & Zhang, Z. M. (2021). Spatial Profiles of Photon Chemical Potential in Near-field Thermophotovoltaic Cells. Journal of Applied Physics,Vol. 129, pp. 213101.