教师名录

工作经历

2023/09 — 至今         3003新葡官方网站，3003新葡官方网站，助理研究员，硕士生导师

2019/09 — 2023/08   清华大学，能源与动力工程系（燃烧能源中心），博士后、助理研究员

教育经历

2014/09 — 2019/06   浙江大学，机械工程学院，机械电子工程专业，博士

2010/09 — 2014/06   西南交通大学，机械工程学院，机械电子工程专业，学士

从事实验流体力学、微纳尺度多相流、空化机理研究，包括三个具体研究方向：

（1）多相流中纳米尺度分散相（纳米气泡、纳米液滴）稳定特性及应用研究：重点关注界面科学领域的体相纳米气泡、纳米液滴等分散相在多相多组分流体系统中的成核、跨尺度演变、动态行为特性和热力学稳定机制。

（2）多相流中宏观气泡/液滴动力学及相变行为特性研究：重点关注气液多相流中气泡或液滴生长、变形、破裂以及相变等行为特性。

（3）流体泛空化作用研究：重点关注纳米级空化核（纳米气泡、纳米聚集体）对于空化作用的影响，研究复杂多相流体系统中的空化特性及空化调控的新方法。

团队研究聚焦流体力学前沿基础问题，开展跨尺度（纳观到宏观）、多学科（流体力学、物理化学、界面科学）的交叉研究，实验仪器完备、条件充足，欢迎报考硕士研究生（招收但不限于力学、流体力学、机械工程、船舶海洋工程、能源动力等背景的学生）。

（1）Current Opinion in Colloid and Interface Science 特刊Nanoprecipitation and nanoemulsification（2025）联合主编

（2）PRL, PRF, IJMF, JFM, Journal of Colloid and Interface Science, Applied Surface Science等流体力学、界面科学期刊审稿人

（8）3003新葡官方网站“深蓝计划”基金项目：面向装备空化性能的海洋水体空化机理研究，2024 ~ 2025，负责人

（7）国家实验室（崂山实验室）公共科研平台建设项目：超高速水洞群设计原理及验证，2023 ~ 2025，子课题负责人

（6）3003新葡官方网站“新进青年教师启动计划”：纳米气泡稳定特性及其对流体空化的影响机制研究，2023 ~ 2026，负责人

（5）国家自然科学基金青年科学基金项目：体相纳米气泡对空化作用的影响机理研究，2023 ~ 2025，负责人

（4）中国博士后科学基金面上项目：体相纳米气泡稳定机制及其控制方法研究，2020 ~ 2021，负责人

（3）国家自然科学基金国际(中德)合作与交流项目：Evidence and Physics of Nanobubbles in Water，2019 ~ 2021，主要参与

（2）国家自然科学基金基础科学中心项目：非线性力学的多尺度问题研究，2019 ~ 2021，参与

（1）清华大学-University of Alberta未来能源和环境联合研究中心项目：用于高效水处理的新型纳米气泡技术，2019 ~ 2021，主要参与

SCI论文（*通讯作者，#共同一作）

2025

[1]      M. Li*, Y. Gao*, Trigger-assisted nanoprecipitation for nanoparticle synthesis: A review, Current Opinion in Colloid and Interface Science, 2025, under review.

[2]      F. Lin, M. Li*, Spreading dynamics of a droplet impinging on a heated granular bed, Physical Review Fluids, 2025, under review.

[3]      Y. Tian, Y. Wakata, D. Zhao, Y. Liu*, M. Li*, B. Wang, On the impact dynamics of droplets on miscible bicomponent liquids: from cavity collapse to jet formation, International Journal of Heat and Mass Transfer, 2025, under review.

[4]      Y. Wakata, M. Li*, C. Sun*, Evaporation dynamics of multicomponent drops: A review, Current Opinion in Colloid and Interface Science, 2025, under review.

[5]      Y. Gao, P. Zhang, H. Luo, C. Chen, J. Niu, Y. Tang, R. Wang, M. Li, X. Xu*, C. Sun*, Thermal response of nanobubble suspensions under freeze-thaw cycles through experiment and molecular dynamics simulations, JCIS, 2025, under review.

[6]      Y. Li, M. Li*, Y. Liu, B. Wang*, Nanoscale mapping of competitive cavitation nucleation pathways: from surface to bulk, JFM, 2025, under review.

[7]      J. Gao, X. Wei*, D. Li, D. Wu, L. Pan, D. Wang, M. Li, Y. Zhang, B. Scheid, Spontaneous breakup and satellite formation of an inviscid liquid bridge, PRF, 2025, under review.

[8]      X. Fan, F. Lin, M. Li, M. Xu*, Directional transport of burning droplets on heated concentric microgroove surfaces with gradient width, International Journal of Heat and Mass Transfer, 2025, under review.  

[9]      F. Lin, M. Li*, Bubble entrainment in turbulent jets leaping from liquid surface, International Journal of Heat and Fluid Flow, 2025, Under Review.

[10]   M. Li*, R. Lai, Y. Tian, Y. Gao*, B. Wang, C. Sun, Uncovering the nanoscopic phase behavior of ternary solutions in the presence of electrolytes: from pre-Ouzo to Ouzo region, Langumir, 2025, under review.  

[11]   J. Gu, Q. Wang, Y. Gao, L. Yi, Y. Liu, M. Li*, B. Wang*, Flow characteristics and microbubble formation in turbulent mixing of a self-sucking Venturi channel, International Journal of Multiphase Flow, 2025, under review.

[12]   J. Cai, Y. Li, Y. Liu, B. Wang, M. Li*, Ionic strength–driven cavitation nucleation: from energy deposition-based to tension-based cavitation, International Journal of Multiphase Flow, 2025, 191: 105306.

[13]   Y. Gao, C. Chen, M. Li*, C. Sun*, Ionic environment-modulated nucleation and stability of multiscale nanodomains in surfactant-free microemulsions, Journal of Colloid and Interface Science, 2025, 696: 137833.

[14]   Y. Li, M. Li*, L. Zhang, B. Wang*, Cavitation inception triggered by transient ambient pressures in electrolyte solutions, Physical Review Fluids, 2025, 10(2): 024202.

[15]   Y. Gao, C. Chen, F. Wang, M. Li, C. Sun*, Review on characterization and removal of contaminants in lithography, SCIENCE CHINA: Physics, Mechanics & Astronomy, 2024, 68(9): 294702.

2024

[16]   C. Chen, Y. Gao, M. Li*, C. Sun*, Unraveling the Phase Behavior and Stability of Surfactant-Free Microemulsions: From Molecular Interactions to Macroscopic Properties, Langmuir, 2024, 40(49): 26227–26238. 

[17]   M. Li*, Y. Li, Y. Gao, C. Sun, B. Wang*, Effect of nanoscale nuclei on the dynamics of laser-induced cavitation, Physics of Fluids, 2024, 36(9): 093307.  

[18]   M. Li*, Y. Gao, X. Ma, C. Chen, B. Wang, C. Sun, How bulk nanobubbles respond to elevated external pressures, Physics of Fluids, 2024, 36(9): 092003.

[19]   Y. Li, M. Li*, L. Zhang, B. Wang*, Bridging the Gap: Unraveling the Role of Nano-gas Nuclei in the Non-Equilibrium Water-Vapor Phase Transition, International Journal of Heat and Mass Transfer, 2024, 232: 125958.

[20]   X. Ma, M. Li*, C. Sun, Effect of ionic environment in aqueous solution on nucleation and stabilization of bulk nanobubbles, Applied Surface Science, 2024, 656: 159726. 

[21]   W. Li, L. Hu, R. Su, W. Liu, M. Li*, On the dynamics of head-on collision of sessile droplets on the travelling substrate, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2024, 682: 132892.

2023

[22]   M. Li*, Y. Wakata, H. Zeng, C. Sun*, On the thermal response of the multiscale nanodomains formed in trans-anethol/ethanol/water surfactant-free microemulsion, Journal of Colloid and Interface Science, 2023, 652: 1944-1953. 

[23]   Hao Zeng, Y. Wakata, X. Chao*, M. Li*, C. Sun*, On evaporation dynamics of a multicomponent droplet: evaporation-triggered phase transition and freezing, Journal of Colloid and Interface Science, 2023, 648: 736-744. 

[24]   X. Ma^#, M. Li^*,#, Xuefei Xu, Chao Sun, On the role of surface charge and surface tension tuned by surfactant in stabilizing bulk nanobubbles, Applied Surface Science, 2023, 608: 155232. 

2022

[25]   M. Li*, L. Yi, C. Sun*, Spontaneously formed multiscale nano-domains in monophasic region of ternary solution, Journal of Colloid and Interface Science, 2022, 628: 223-235. 

[26]   Y. Gao, M. Li*, C. Sun, X. Zhang*, Microbubble-enhanced water activation by cold plasma, Chemical Engineering Journal, 2022, 446: 137318. (JCR Q1, IF: 16.7)

[27]   X. Ma^#, M. Li^*,#, P. Pfeiffer, J. Eisener, C-D. Ohl, C. Sun*, Ion adsorption stabilizes bulk nanobubbles, Journal of Colloid and Interface Science, 2022, 606: 1380-1394.

[28]   X. Ma, M. Li*, X. Xu, C. Sun, Coupling effects of ionic surfactants and electrolytes on the stability of bulk nanobubbles, Nanomaterials, 2022, 12(19): 3450. 

[29]   X. Ma, M. Li*, C. Sun, Measurement and characterization of bulk nanobubbles by Nanoparticle Tracking Analysis method, Journal of Hydrodynamics, 2022. 

[30]   W. Li, L. Hu*, M. Li, W. Liu, S. Su, Morphological characteristics of the drop on the travelling substrate with a sharp stepped configuration. Experimental Thermal and Fluid Science, 2022, 132: 110551. 

[31]   P. Pfeiffer*, J. Eisener*, H. Reese, M. Li, X. Ma, C. Sun, C-D. Ohl, Thermally assisted Heterogeneous Cavitation through Gas Supersaturation. Physical Review Letters, 2022, 128: 171101. 

2021

[32]   M. Li, X. Ma, J. Eisener, P. Pfeiffer, C-D. Ohl*, C. Sun*, How bulk nanobubbles are stable over a wide range of temperatures, Journal of Colloid and Interface Science, 2021, 596: 184-198. 

2020

[33]   M. Li, L. Hu*, Experimental investigation of the behaviors of highly deformed bubbles produced by coaxial coalescence. Experimental Thermal and Fluid Science, 2020, 117: 110114. 

[34]   M. Li, W. Li, L. Hu*, Jet formation and breakup inside highly deformed bubbles. International Journal of Heat and Mass Transfer, 2020, 163: 120507. 

[35]   L. Hu, H. Xu, M. Li, W. Liu, W. Chen, H. Xie, X. Fu*, Liquid jet formation during a suspended liquid suction process. Experimental Thermal and Fluid Science, 2020, 114: 109952. 

[36]   L. Hu, W. Li, M. Li, Y. Huang, X. Fu*, Morphological characteristics of gas-liquid interfaces receding through the mesoscopic gap with a sharp feature. Colloids and Surfaces A, 2020, 594: 124629. 

2019

[37]   M. Li, L. Hu*, H. Xu, W. Chen, H. Xie, X. Fu, Jet formation during the gas penetration through a thin liquid layer. Physics of Fluids, 2019, 31(1): 017105. 

[38]   M. Li, L. Hu*, W. Chen, H. Xie, X. Fu, Submerged injection of gas into a thin liquid sheet. International Journal of Multiphase Flow, 2019, 110: 118-131. 

2016

[39]   L. Hu, M. Li, W. Chen, H. Xie, X. Fu*, Bubbling behaviors induced by gas-liquid mixture permeating through a porous medium. Physics of Fluids, 2016, 28: 087102. 

[1]  付新，厉明波，胡亮，陈文昱，一种用于浸没式光刻机的微流道气液分离回收装置，CN107991843A（2023.07.21）

[2]  付新，厉明波，胡亮，陈文昱，用于浸没式光刻机的微流道气液分离回收装置，CN207601509U（2018.07.10）

[3]  一种具有气液分离回收功能的浸液供给回收装置，CN113138540A（2024.02.09）

（1）第十二届（2021）全国实验流体力学学术会议优秀报告

（2）第十三届（2024）中国颗粒大会优秀青年报告

（3）第十四届（2025）全国实验流体力学学术会议优秀报告