教育背景

1994/09-1998/07，西安交通大学，热能工程，学士

2000/09-2003/03，上海交通大学，热能工程，硕士

2004/09-2008/06，上海理工大学，工程热物理，博士

工作经历

2003/03-至今，上海理工大学，能源与动力工程学院，讲师/副教授/教授

2007/03-2008/03，美国密苏里大学，访问学者

负责的科研项目

1、脉冲激光加热的微尺度导热和熔化耦合传热问题研究，国家自然科学基金

2、具有非傅里叶效应的微纳米颗粒固液相变传热研究，国家自然科学基金

3、金属材料表面加工中的相变传热研究，上海市科委自然基金

4、纳米流体非常规热物理特性的分子动力学研究，高等学校博士点专项基金

5、周期性通道内的流动与换热研究，上海市教委发展基金

6、基于性能数值模拟的凝汽器孪生技术研究，上海电气电站设备有限公司

7、锂离子电池劣化及安全性测试，中北大学

8、热力系统优化算法研究，上海汽轮机厂有限公司

9、电厂热力性能在线评估关键技术研究，上海电气电站设备有限公司

10、发电机组汽轮机冷端系统优化研究，宝山钢铁股份有限公司

11、蒸汽冷却器计算分析，中国船舶重工集团公司第719研究所

12、3号机组供热测试与热平衡特性分析，上海金艺检测技术有限公司

13、汽车散热器性能测试，德朗汽车零部件有限公司

14、能源审计，日泰（上海）汽车标准间有限公司

15、能源审计，上海宏力半导体有限公司

16、能源利用状况分析，上海海立铸造有限公司

代表性论文

1.      Wang, Z., Li, L*.,Regulation of rapid boiling of nanofluids on the hybrid wall: A molecular dynamics simulation, International Journal of Heat and Mass Transfer 183 (2022) 122059

2.      Wang, Z., Li, L*.,Molecular dynamics simulation of explosive boiling of the H2O-Cu nanofluid, Journal of Molecular Liquids 332 (2021) 115847

3.      Wang Q., Li, L*., Yang M., Melting characteristics and dynamic evolution of microstructure of single-crystal gold film irradiated by laser under the non-Fourier effect, Molecular Crystals and Liquid Crystals, 2021.2

4.      Yi Liu, Ling Li⁎, Jianli Wang, A novel relation for heat flow using Maxwell thermoelectricity analogy,International Communications in Heat and Mass Transfer 117 (2020) 104745

5.      Yi Liu, Ling Li⁎, Yuwen Zhang, Numerical simulation of non-Fourier heat conduction in fins by lattice Boltzmann method, Applied Thermal Engineering 166 (2020) 114670

6.      Zhao Wang, Ling Li ⁎, Mo Yang, Molecular dynamics simulation of the wetting characteristics of a nanofluid droplet on rough substrate, Journal of Molecular Liquids 319 (2020) 114204

7.      Bo Wang, Yi Liu, Ling Li⁎, Nanofluid double diffusive natural convection in a porous cavity under multiple force fields, Numerical Heat Transfer, Part A, 2020, 77(4): 343–360.

8.      Yi Liu, Ling Li⁎, Qin Lou, A hyperbolic lattice Boltzmann method for simulating non-Fourier heat conduction, International Journal of Heat and Mass Transfer 131 (2019) 772–780

9.      Yi Liu, Ling Li⁎, Lattice Boltzmann simulation of non-Fourier heat conduction with phase change, Numerical Heat Transfer, Part A, 2019, 76(1): 19–31.

10.  Ling Li⁎, Mingyang Wu, Ling Zhou, Lattice Boltzmann Simulations for Melting and Resolidification of Ultrashort Laser Interaction with Thin Gold Film, Int J Thermophys (2018) 39:88

11.  Li, L*., Zhao, Sh.,Thermal ablation of thin gold films irradiated by ultrashort laser Pulses，Appl. Phys. A (2016) 122:437

12.  Li, L*., Zhou, L., Yang,M., An Expanded Lattice Boltzmann Method for Dual Phase Lag model,International Journal of Heat and Mass Transfer, 93 (2016) 834–838

13.  Li, L*., Zhou, L., Shan,Y., Yang, M., Analysis of Rapid Melting and Resolidification in FemtosecondLaser Interaction with Nanoparticle, Numerical Heat Transfer, Part A,2016,  Volume: 69, Issue: 08, pages 859 -873

14.  H. Zhang, Y.G. Shan, L.Li, M. Lu, R. Li, Modeling the self-assembly of nanoparticles into branchedaggregates from a sessile nanofluid droplet, Applied Thermal Engineering, 94(2016) 650–656

15.  Li, L*., Zhou, L., Shan,Y., Zhang, Y., Investigation on Heat Transfer Mechanism of Ultrashort LaserInteraction with Metals, Int J Thermophys (2015) 36:183–203

16.  Zhou, L., Li, L*., Zhang,Y., and Shan, Y., Source Distribution Based on Mie's Scattering Theory for HeatConduction in Nanoparticle Subject to Ultrashort Laser Irradiation, NumericalHeat Transfer, Part A, 2014, 66: 605–621.

17.   Zhou, L., Li, L*.,Melting and resolidification of gold film irradiated by laser pulses less than100 fs, Appl. Phys. A (2014) 116:2157-2165.

18.  Li, L*., Zhou, L., Zhang,Y., Thermal Wave Superposition and Reflection Phenomena during FemtosecondLaser Interaction with Thin Gold Film, Numerical Heat Transfer, Part A:Applications , 2014, Volume: 65, Issue: 12, pages 1139 – 1153.

19.  Kang, H., Zhang, Y.,Yang, M., and Li, L., 2012, “Molecular Dynamics Simulation on Effect ofNanoparticle Aggregation on Transport Properties of a Nanofluid,” ASME Journalof Nanotechnology in Engineering and Medicine, 3(2), 021001.

20.  Wang, Z., Yang, M., Li,L., and Zhang, Y., 2012, “Oscillation and Chaos in Combined Heat Transfer byNatural Convection-Conduction and Surface Radiation in an Open Cavity,” ASMEJournal of Heat Transfer, 134(9), 094501.

21.  Kang, H., Zhang, Y.,Yang, M., and Li, L., 2012, “Nonequilibrium Molecular Dynamics Simulation ofCoupling between Nanoparticles and Base-Fluid in a Nanofluid,” Physics LettersA, 376(4), 521-524.

22.  Wang, Z., Yang, M., Li,L., and Zhang, Y., 2011, “Combined Heat Transfer by NaturalConvection-Conduction and Surface Radiation in an Open Cavity under ConstantHeat Flux Heating,” Numerical Heat Transfer, Part A: Applications, 60(4),289-304.

23.  Li, L., Zhang, Y., Ma, H.B., and Yang, M., 2010, “Molecular Dynamics Simulation of Effect of LiquidLayering around the Nanoparticle on the Enhanced Thermal Conductivity ofNanofluids,” Journal of Nanoparticle Research, 12(3), 811-821.

24.  Zhang, Y., Li, L., Ma, H.B., and Yang, M., 2009, “Effect of Brownian and Thermophoretic Diffusions ofNanoparticles on Nonequilibrium Heat Conduction in a Nanofluid Layer withPeriodic Heat Flux,” Numerical Heat Transfer, Part A, 56(4), 325-341.

25.  Li, L., Zhang, Y., Ma, H.B., and Yang, M., 2008, “An Investigation of Molecular Layering at theLiquid-Solid Interface in Nanofluids by Molecular Dynamics Simulation,” PhysicsLetters A, 372(25), 4541–4544.

26.  Li, L., Yang, M., andZhang, Y., 2008, “Numerical Study of Periodically Fully-Developed Convection inChannels with Periodically Grooved Parts,” Int. J. Heat Mass Transfer, Vol. 51,No. 11-12, 3057-3065, 2008.

27.  N.Y. Zhan, M. Yang, Z.Y.Wang, L. Li and Z.Z. Zheng, Three-dimensional simulation of Rayleigh-Bénardconvection in a rectangular cavity, Progress in Computational Fluid Dynamics,Vol. 8, 2008, pp. 526-535

荣誉及人才项目

1、2023年，上海市东方英才拔尖计划

2、2023年，全国高校黄大年式教师团队成员

3、2021年，上海市教卫工作党委系统优秀共产党党员·师德标兵

4、2021年，上海市教卫工作党委系统优秀共产党党员

5、2018年，上海市教育系统巾帼建功标兵

教学及科研获奖

1、2023年，“工程热力学”获评国家级一流课程，负责人

2、2023年，上海市教学成果奖一等奖

3、2023年，上海市教学成果奖二等奖

4、2021年，“工程热力学”获评上海市一流课程，负责人

5、2021年，“工程热力学”获评上海高校党史学习教育与课程相融合示范课程，负责人

6、2017、2016、2015、2008年，校教学质量优秀奖一等奖

7、2023年、2014、2006年三次获评海理工大学“同学心目中的好老师”

8、2014年，机械工业联合会科技进步二等奖

【本科生课程】工程热力学、传热学、工程热应用与分析