王绍宇   讲师, 工程热物理研究中心教师

联系方式： oleewsy@gmail.com

研究方向：

• 液态金属湿润动力学

• 微纳尺度相变换热

• 微型设备热管理技术

承担项目：

• 国家自然科学基金重点项目. 项目名称：微纳液滴动力学特性及操控液滴强化热质传递的基础研究，起止日期：2020.1-2024.12（主要参与人）

• 国家自然基金创新研究群体. 项目名称：能量传递转化与高效动力系统究，起止日期：2019.1-2024.12 （主要参与人）
  

• 国家自然科学基金. 项目名称：传热传质学，起止日期：2016.1-2020.12 （主要参与人）

期刊论文：

●Wang S Y, Wang Z J, Wang D Q, Wang Y B, Wang Y F, Zhang B X, Yang Y R, Wang X D*, Lee D J*. Vapor nucleation on hybrid-wetting nano-convex surfaces: The competition between intrinsic wettability and topography. Langmuir, 2024, 40: 24162-24173. (SCI/EI)

● Wang Z J, Wang S Y*, Wang D Q, Yang Y R, Wang X D*, Lee D J. The growth of condensed nanodroplets in electric fields: A molecular dynamics study. International Journal of Heat and Mass Transfer, 2024, 226: 125511. (SCI/EI)

●Wang S Y, Wang Z J, Wang D Q, Yang Y R, Wang X D*, Lee D J*. Electrically manipulated vapor condensation on the dimpled surface: Insights from molecular dynamics simulations. Langmuir, 2023, 39, 829-840. (SCI/EI)

●Wang S Y, Wang Z J, Wang D Q, Yang Y R, Zheng S F, Gao S R, Wang X D*, Lee D J*. Nucleation of water vapor on nanodimpled surfaces: Effects of curvature radius and surface wettability. Applied Thermal Engineering, 2023, 219, 119437. (SCI/EI)

●Wang S Y, Wang Z J, Wang S L, Yang Y R, Huang C L*, Wang X D*. Non-isothermal dissolutive wetting of Al-Ni and Cu-Ni alloy nanodroplets on a Cu(100) substrate. Journal of Thermal Science, 2022, 31(4): 1135-1144. (SCI/EI)

●Wang S Y, Wang S L, Yang Y R, Wang X D*, Lee D J. High-temperature reactive wetting systems: Role of lattice constant. Chemical Engineering Science, 2019, 209: 115206. (SCI/EI)

●Wang Z J, Wang S Y, Wang D Q, Yang Y R, Wang X D*, Lee D J. Whether nano hydrophilic spots control the condensation pattern: The mechanism of critical wettability. International Communications in Heat and Mass Transfer, 2024, 158: 107952. (SCI/EI)

●Wang Z J, Wang S Y, Wang D Q, Yang Y R, Wang X D^*, Lee D J^*. Water vapor condensation on substrates with nanoscale hydrophilic spots: A molecular dynamics study. International Journal of Heat and Mass Transfer, 2023, 205: 123929. (SCI/EI)

●Wang Z J, Wang S Y, Wang D Q, Yang Y R, Wang X D*, Lee D J*. Water vapor condensation on binary mixed substrates: A molecular dynamics study. International Journal of Heat and Mass Transfer, 2022, 184: 122281. (SCI/EI)

●Wang Y H, Wang S Y, Lu G*, Wang X D*. Effects of wettability on explosive boiling of nanoscale liquid films: Whether the classical nucleation theory fails or not?.  International Journal of Heat and Mass Transfer, 2019, 132: 1277-1283.  ((SCI/EI)

●Wang Y H, Wang S Y, Lu G*, Wang X D*. Explosive boiling of nano-liquid argon films on high temperature platinum walls: Effects of surface wettability and film thickness. International Journal of Thermal Sciences, 2018, 132: 610-617. (SCI/EI)

●Wang D Q, Wang Z J, Wang S Y, Yang Y R, Zheng S F*, Wang X D*. Coalescence-induced wetting transition of water droplets on nanostructured surface. International Communications in Heat and Mass Transfer, 2025, 162: 108585. (SCI/EI)

●Wang Y B, Wang Y F, Wang S Y, Zhang B X, Yang Y R, Wang X D*. Impact of a nanodroplet on liquid surfaces. Physics of Fluids, 2024, 36: 032023. (SCI/EI)

●Liu H X, Wang Y B*, Wang S Y, Yan K C, Yang Y R, Wang X D*. Working regime criteria for microscale electrohydrodynamic conduction pumps. Langmuir, 2023, 39(49): 18052-18059. (SCI/EI)

●Wang D Q, Wang Z J, Wang S Y, Yang Y R, Zheng S F*, Lee D J, Wang X D*. Coalescence-induced jumping of nanodroplets in a perpendicular electric field: A molecular dynamics study. Langmuir, 2024, 40(6): 3248-3259. (SCI/EI)

●Zhang B X, Fu X Y, Lu W, Zhu K Q, Wang Y B, Wang S Y, Yan Y R, Wang X D*. The effect of retraction-rebound dynamics on the contact time of rebounding-coalescing droplets on a superhydrophobic surface with or without a macro-ridge. Physics of Fluids, 2025, 37: 012101. (SCI/EI)

●Wang Y B, Liu H X, Wang C X, Yan K C, Wang S Y, Zhang B X, Bo Z, Yang Y R, Wang X D*. Effect of electrode arrangement on heat transfer enhancement by electrohydrodynamic conduction pumps in a rectangular channel. Applied Thermal Engineering, 2025, 259: 124884. (SCI/EI)

●Wang Y B, Yan K C, Wang C X, Wang S Y, Zhang B X, Yang Y R, Wang X D*. Optimization study on fluid flow and heat transfer in a rectangular channel with cross-scale ribs for turbine blade internal cooling. Physics of Fluids, 2024, 36: 125109. (SCI/EI)

●Zhang B X, Zhang Y Y, Lu W, Lee D J, Wang S Y, Wang Y B, Yan W M, Hsu S H, Yang Y R, Wang X D*. Rebound dynamics of multiple droplets symmetrically/asymmetrically impacting macrotextured superhydrophobic surfaces. Chemical Engineering Science, 2024, 299: 120550. (SCI/EI)

●Zhang B X, Wang L Q, Lu W, Zhu K Q, Wang Y B, Wang S Y, Yang Y R, Wang X D*. The overall thermal performance enhancement in an internal cooling channel by the hierarchical-truncated rib scheme. Physics of Fluids, 2025, 37: 025173. (SCI/EI)