教育背景

工作经历

研究方向

•大功率电子器件散热技术

•纳米孔内液体蒸发传热机理

•微纳结构毛细流动与蒸发

•薄液膜沸腾气泡动力学

课程教学

•《分子气体动力学理论基础》研究生专业课

•《能源利用综合实验》本科生必修课

•《地热能及其利用技术》本科生专业必修课

•《能源概论》本科生专业课

奖项荣誉

•教育部科学研究优秀成果奖，二等奖，排名第5

•yl6809永利集团立德树人优秀班主任

•星火基金重点项目指导教师，结题优秀

•yl6809永利集团杰出学子计划导师

•北京市老员工节能减排竞赛特等奖，指导教师

•全国老员工节能减排竞赛三等奖，指导教师

主要科研项目

1)中国博士后科学基金面上项目，《基于非均匀纳米多孔薄膜自吸蒸发的芯片近结冷却技术研究》，主持，结题，8万元；

2)国家自然科学基金青年基金，《含不凝气条件下纳米孔内液体蒸发传热机理的研究》，主持，结题，30万元；

3)北京市自然科学基金面上项目，《基于AAO纳米多孔薄膜毛细蒸发的芯片近结冷却技术研究》，主持，结题，20万元；

4)北京市教委科技计划一般项目，主持，结题，15万元；

5)国家自然科学基金面上项目，《横向供液薄膜沸腾气泡动力学及强化传热机理研究》，主持，在研，64.1万元；

6)yl6809永利集团博士科研启动金，主持，5万元；

7)yl6809永利集团青年优秀人才科研经费，主持，50万元。

主要论文论著

[1]Ding, R., Xia, G.^*,Li, R.^*,Song, C., Li, C. Thermal performance of microchannel-nanoporous membrane composite wicks in ultra-thin heat pipes: An experimental study.International Journal of Heat and Mass Transfer.2026, 256: 127970.

[2]Li, R.^*, Yan, Z., Cheng, X., Wang, Y., Xia, G. Liquid evaporation from nanochannel with rough wall surface by direct simulation Monte Carlo.International Journal of Multiphase Flow.2025, 192: 105352.

[3]Zhao, P., Xia, G^*.,Li, R^*. Nanopore evaporation prediction model with a complete explanation of the equivalent evaporation coefficient.Physics of Fluids.2025, 37(1): 012030.

[4]Li, F., Xia, G^*.,Li, R^*. Visual boiling experimental research based on lateral liquid supply structure.International Journal of Heat and Fluid Flow.2025, 111: 109664.

[5]Li, R., Xia, G. Liquid evaporation from nanochannel in the presence of non-condensable gas by direct simulation Monte Carlo.Journal of Molecular Liquids.2024, 399: 124378.

[6]李冉,夏国栋.纳米孔内液体蒸发建模及不凝气影响研究.中国科学:物理学 力学 天文学,2024, 54(2): 224705.

[7]Li R, Yan Z, Xia G. Effect of inter-pore interference on liquid evaporation rates from nanopores by direct simulation Monte Carlo.Physics of Fluids,2023, 35(3): 032015.

[8]Li, R.,Xia, G. Improved heat dissipation performance of nano-porous wicking evaporator by structural modification: A numerical study.Applied Thermal Engineering.2022, 212: 118604.

[9]Li, R.,Xia, G., Wang, J. Two-dimensional kinetic evaporation by direct simulation Monte Carlo (DSMC) with independently controlled downstream boundary conditions.International Journal of Heat and Mass Transfer.2022, 194: 123075.

[10]Li, R.,Wang, J., Xia, G. New model for liquid evaporation and vapor transport in nanopores covering the entire Knudsen regime and arbitrary pore length.Langmuir.2021, 37(6): 2227-2235.

[11]Li, R.,Wang, J., Xia, G. Theoretical and numerical study of nanoporous evaporation with receded liquid surface: effect of Knudsen number.Journal of Fluid Mechanics.2021, 928: A9.

[12]黄中伟,杨睿月,武晓光,李冉.《液氮射流应用基础研究》,科学出版社, 2021.

[13]Li, R.,Zhang, C., Huang, Z. Quenching and rewetting of rock in liquid nitrogen: Characterizing heat transfer and surface effects.International Journal of Thermal Sciences.2020, 148: 106161.

[14]Li, R.,Yan, Y., Huang, Z. Thermal and mechanical analysis of LN₂jet impinging on rock surface.Applied Thermal Engineering.2020, 178: 115581.

[15]Li, R.,Wu, X., Huang, Z. Jet impingement boiling heat transfer from rock to liquid nitrogen during cryogenic quenching.Experimental Thermal and Fluid Science.2019, 106: 255-264.

[16]Li, R.,Huang, Z., Wu, X., Yan, P., Dai, X. Cryogenic quenching of rock using liquid nitrogen as a coolant: Investigation of surface effects.International Journal of Heat and Mass Transfer.2018, 119: 446-459.

[17]Li, R.,Huang, Z. Estimating the transient thermal boundary conditions with an improved space marching technique.International Journal of Heat and Mass Transfer.2018, 127: 59-67.

[18]Li, R.,Huang, Z. A new CHF model for enhanced pool boiling heat transfer on surfaces with micro-scale roughness.International Journal of Heat and Mass Transfer.2017, 109: 1084-1093.

[19]Li, R.,Huang, Z., Li, G., Wu, X., Yan, P. Study of the conductive heat flux from concrete to liquid nitrogen by solving an inverse heat conduction problem.Journal of Loss Prevention in the Process Industries.2017, 48: 48-54.

[20]Li, R.,Huang, Z., Li, G., Wu, X., Yan, P. A modified space marching method using future temperature measurements for transient nonlinear inverse heat conduction problem.International Journal of Heat and Mass Transfer.2017, 106: 1157-1163.