王沫然，博士，清华大学长聘教授，博士生导师。1995年考入清华大学工程力学系，1999年和2004年分别获得清华大学工程力学系学士和博士学位。2004~2008年先后在美国约翰霍普金斯大学(Johns Hopkins University)和美国加州大学(University of California)作博士后，2008年获得美国能源部J. Robert Oppenheimer Fellowship，并进入Los Alamos国家实验室工作，任奥本海默(Oppenheimer Fellow)。2011年进入清华航天航空学院工程力学系工作，任教授。
王沫然教授课题组正招收流体力学与传热传质方向的博士和硕士研究生，以及交叉学科（力学、热学、物理、化工、环境、地质、石油、材料等）背景的博士后研究人员，有热爱科学、愿意投身科研的同学请联系：，mrwang/at/tsinghua.edu.cn

教育背景1999.7 清华大学工程力学系 学士学位
2004.7 清华大学工程力学系 博士学位

工作履历2004-2006 美国约翰霍普金斯大学，博士后 (Postdoctoral Fellow)
2006-2008 美国加州大学戴维斯分校，博士后 (Research Associate)
2008-2011 美国Los Alamos国家实验室，奥本海默 (Oppenheimer Fellow)
2007-2012美国约翰霍普金斯大学，访问科学家 (Visiting Scientist)
2018-2019 美国普林斯顿大学，访问教授 (Visiting Professor)
2011-至今清华大学航天航空学院工程力学系，教授

学术兼职学会会员：ASME(2003至今)，APS(2005至今)，AGU(2009至今)，Interpore(2013至今，lifetime member)，中国力学学会，中国工程热物理学会
学术服务：2006年至今担任过十几个国际期刊的副主编或编委，现任8个国际SCI期刊编委，多次作为会议组织者或学术委员会成员组织国际会议或论坛，担任过美国NSF评审人和能源部及NASA外审专家委员会委员，担任财政部、国资委、基金委以及留学基金委等机构的评审委员会成员。担任编委的期刊包括：
· Journal of Fluid Engineering-ASME期刊编委（Associate Editor）ASME出版，SCI
· Journal of Geophysical Research期刊编委（Associate Editor）AGU出版，SCI
· Journal of Colloid and Interface Science期刊编委（Editorial Board Member）Elsevier出版社，SCI
· Energy期刊编委（Associate Editor）Elsevier出版社，SCI，（2012-1017）
· Energies期刊编委（Editorial Board Member）SCI
· Energy Science and Engineering期刊编委（Editorial Board Member）Wiley出版社，SCI
· Journal of Porous Media期刊编委（Associate Editor）Belgellhouse出版社，SCI
· Transport in Porous Media期刊编委（Editorial Board Member）Springer出版社，SCI
· Special Topics & Reviews in Porous Media期刊编委（Associate Editor）Belgellhouse出版社，SCI
· Advances in Mechanical Engineering期刊编委（Editorial Board & Advisor Board Member）SAGE出版社，SCI，（2008-2019）
· Colloid and Interface Science期刊编委（Editorial Board Member），SCI，（2015-2019）

研究领域研究兴趣及计划：
1．微纳尺度流动及界面输运（流动、扩散及能量传递）
2．微观渗流力学及多物理化学耦合输运（非常规油气、碳储存及水净化）
3．多尺度模拟及应用（LBM, MC, MD, BD, PIC等）
4．复杂流体（电动、气泡、颗粒、相变、乳化、软物质等）
5．传热物理及热管理（量子能量输运、转化及存储机理及热力学优化）
以往工作及贡献：
1．微纳电动流体输运机理及应用
2．多相多孔材料构效关系的定量分析
3．高努森数非理想气体流动及换热模拟
4．微系统（传感器、微泵、微喷等）与微材料的性能分析
5．微纳热量输运机理及非Fourier效应分析
6．输运网络结构的热力学优化
研究概况一直从事微纳尺度流动与界面输运、渗流及多尺度模拟、能质渗流及构效关系、以及传热物理及系统应用的基础研究，在微尺度渗流、界面输运及多尺度模拟方面成果得到国内外同行广泛关注。已在（Peer Reviewed）学术会议及期刊上发表论文200余篇，多次受邀撰写英文著作/章节，担任客座编辑出版英文专刊11本，多次受邀在高影响国际期刊(IF>10)撰写专题综述/评述论文，在8个国际学术期刊(SCI)担任副主编或编委。
主持自然科学基金项目、中组部人才项目、科技部重大专项、科技部重点研发计划、教育部基金项目、国家实验室开放基金项目资助以及中石油和高校等协作项目，作为主要骨干参与自然基金委创新群体项目以及973节能项目；在美国工作期间，作为负责人主持美国能源部国家实验室研究发展(DOE-LDRD)项目和美国国家纺织中心(NTC)项目，作为主要骨干参与美国自然科学基金(NSF)项目和其他美国国家级的科研项目；博士期间参与中国国家自然科学基金重点项目和国家重点基础研究发展项目。

奖励与荣誉2019国际多孔介质学会Interpore P&G Award for Porous Media Research
2019国家高层次人才特殊支持计划—领军人才
2014-19Elsevier高被引中国
2018科技部创新人才推进计划—科技创新领军人才
2013吴仲华优秀青年奖
2011国家海外高层次人才引进计划--青年项目（首批）
2008美国能源部J. Robert Oppenheimer Fellowship Award
2006教育部全国优秀博士论文提名奖
2004清华大学“学术新秀”奖、优秀博士论文及优秀博士毕业生

学术成果发表学术论文两百余篇，其中SCI收录论文 150 余篇，论文SCI引用超过 5000 次，H因子 38 （Web of Science核心版, 截至2019年9月），Google Scholar总引用7700余次，H因子45；多次在高影响因子 (IF>10)的期刊（包括 Physics Reports、Surface Science Reports、Materials Science and Engineering R: Reports和Progress in Materials Science等）发表专题综述。应主编邀请撰写英文书章节7章，合编英文专刊10本，中文教材及工具书5本。
代表性论文
综述文章 (selected 5)
· M. Wang, N. Pan. Predictions of Effective Physical Properties of Complex Multiphase Materials. Material Science and Engineering-R: Reports. 63(1): 1-30, 2008 [约稿当年IF=17.731]
· M. Wang. The Physical Chemistry of Materials: Energy and Environmental Applications. Materials Today. 13(3): 67, 2010 [约稿当年IF=12.929]
· X. Wang, B. Ding, G. Sun, M. Wang and J. Yu. Electro-spinning/netting. Progress in Materials Science.58: 1173-1243, 2013 [约稿当年IF =25.87]
· Y. Guo, M. Wang. Phonon hydrodynamics and its applications in nanoscale heat transport. Physics Reports. 595: 1-44, 2015 [约稿当年IF =22.91]
· H. Tian, M. Wang. Electrokinetic mechanisms of wettability alternation at oil-water-rock interface. Surface Science Reports 72: 369-391, 2017 [约稿当年IF =13.33]
微纳气体渗流机理(selected 5)
· Z.Y. Wang, M. Wang* S. Chen. Coupling of high-Knudsen and non-ideal gas effects in microporous media. Journal of Fluid Mechanics 840: 56-73, 2018
· X.T. He#, Y.Y. Guo#, M. Li, N. Pan and M. Wang*. Effective gas diffusion coefficient of fibrous materials by mesoscopic modeling. International Journal of Heat and Mass Transfer 107: 736-746, 2017
· M. Wang, X. Lan and Z. Li*. Analysis of Gas flows in Micro- and Nanochannels. Int. J. Heat Mass Transfer. 51(13-14): 3630-3641, 2008
· M. Wang, Z. Li*. Simulations for gas flows in microgeometries using the direct simulation Monte Carlo method. Int. J. Heat Fluid Flow, 25(6): 975-985, 2004
· M. Wang *, Z. Li. Nonideal gas flow and heat transfer in micro- and nanochannels using the direct simulation Monte Carlo method. Physical Review E. 68: 046704, 2003
微纳液体电动渗流机理(selected 5)
· L. Zhang, C. McNeece, M. Hesse and M. Wang *. Reactive Transport of Proton in Electro-osmostic Displacement Flow with Concentration Difference in Microchannel. Analytical Chemistry 90 (20): 11802–11811, 2018
· L. Zhang, M.A. Hesse and M. Wang. Transient solute transport with sorption in Poiseuille flow. Journal of Fluid Mechanics 828: 733-752, 2017
· J. Liu, M. Wang, S. Chen and M. Robbins*. Uncovering Molecular Mechanisms of Electrowetting and Saturation with Simulations. Physical Review Letters. 108: 216101, 2012
· M. Wang*, and A. Revil. Electrochemical charge of silica surfaces at high ionic strength in narrow channels. J. Colloid Interface Sci 343: 381-386, 2010
· M. Wang* and Q. Kang. Electrokinetic transport in microchannels with random roughness. Analytical Chemistry 81 (8), 2953-2961, 2009
微孔介质多物理化学耦合输运(selected 5)
· Y.K. Yang, M. Wang*. Pore-scale modeling of chloride ion diffusion in cement microstructures. Cement and Concrete Composites 85: 92-104, 2018
· L. Zhang and M. Wang*. Electro-osmosis in inhomogeneously charged microporous media by pore-scale modeling. Journal of Colloid and Interface Science. 486: 219-231, 2017
· L. Zhang, M. Wang*. Modeling of electrokinetic reactive transports using a coupled lattice Boltzmann method. Journal of Geophysical Research-Solid Earth. 120: 2877-2890, 2015
· M. Wang*, Q. Kang, H. Viswanathan and B. Robinson. Modeling of electro-osmosis of dilute electrolyte solutions in silica microporous media. J. Geophysical Research-Solid Earth 115: B10205, 2010
· M. Wang*, and S. Chen. Electroosmosis in homogeneously charged micro- and nanoscale random porous media. J. Colloid Interface Sci. 33(15): 264-273, 2007
微纳声子流体力学输运机理(selected 5)
· Y. Guo, D. Jou, M. Wang*. Nonequilibrium thermodynamics of phonon hydrodynamic model for nanoscale heat transport. Physical Review B 2018
· Y. Guo, M. Wang*. Phonon hydrodynamics for nanoscale heat transport at ordinary temperature. Physical Review B 97: 035421, 2018
· Y. Guo, M. Wang*. Heat transport in two-dimensional materials by directly solving phonon Boltzmann equation under Callaway’s dual relaxation model. Physical Review B 96: 134312, 2017
· Y. Guo, D. Jou, M. Wang* Macroscopic heat transport equations and heat waves in nonequilibrium states. Physica D-Nonlinear Phenomena 342: 24-31, 2017
· M. Wang*, N. Yang and Z. Guo. Non-Fourier heat conductions in nanomaterials. Journal of Applied Physics, 110: 064310, 2011
微尺度能量渗流 (selected 5)
· C. Xie, J. Wang N. Pan, D. Wang and M. Wang*. Lattice Boltzmann modeling of thermal conduction in composite materials with thermal contact resistance. Communications in Computational Physics. 17: 1037-1055, 2015
· M. Wang*, X. Wang, J.K. Wang and N. Pan. Grain size effects on effective thermal conductivity of porous materials with internal thermal contact resistance. Journal Porous Media. 16(11): 1043-1048, 2013
· M. Wang*, N. Pan. Modeling and prediction of the Effective Thermal Conductivity of Random Open-cell Porous Foams. Int. J. Heat Mass Transfer. 51(5-6): 1325-1331, 2008
· M. Wang, J. He, J. Yu and N. Pan. Lattice Boltzmann modeling of the effective thermal conductivity for fibrous materials. Intentional Journal of Thermal Sciences 46(9): 848-855, 2007
· M. Wang*, J. Wang, N. Pan, and S. Chen. Mesoscopic Predictions of the Effective Thermal Conductivity of Microscale Random Porous Media. Physical Review E. 75: 036702, 2007
热力学及优化(selected 5)
· Y. Guo, Z. Y. Wang, M. Wang*. Thermodynamic extreme principles for non-equilibrium stationary state in heat conduction. Journal of Heat Transfer 139(7): 071303, 2017
· Y. Guo, M. Wang*. Thermodynamic analysis of gas flow and heat transfer in microchannels. International Journal of Heat and Mass Transfer 103: 773-782, 2016
· X. Shan, M. Wang* and Z. Guo. Geometry optimization of self-similar transport network. Mathematical Problems in Engineering. 2011: 421526, 2011
· X. Liu, M. Wang*, J. Meng, E. Ben-Naim and Z. Guo. Minimum dissipation principle for the optimization of transport networks. International Journal of Non-linear Science and Numerical Simulations 11(2): 113-120, 2010
· Q. Chen, M. Wang*, N. Pan, and Z. Guo. Optimization principles for convective heat transfer enhancement. Energy. 34(9): 1199-1206, 2009
页岩油/气勘探开发中的输运(selected 5)
· C.Y. Xie, W. Lv, and M. Wang*. Shear-thinning or Shear-thickening Fluid for Better EOR? — A Direct Pore-scale Study. Journal of Petroleum Science and Engineering 161: 683-691, 2018
· Q. Lv, Z. Chen and M. Wang*. An improved elastic-tube model for the correlation of permeability and stress with correction for the Klinkenberg effect. Journal of Natural Gas Science and Engineering 48: 24-35, 2017
· J. Zheng, Z. Wang, W. Gong, Y. Ju and M. Wang*. Morphology effects of shale nanopores on gas permeability using lattice Boltzmann modeling. Journal of Natural Gas Science and Engineering 47: 83-90, 2017
· Z.Y. Wang, X. Jin, X. Wang, L. Sun, M. Wang*. Pore-scale geometry effects on gas permeability in shale. Journal of Natural Gas Science and Engineering 34: 948-957, 2016
· Z.Y. Wang, Y.Y. Guo, M. Wang*. Permeability of high-Kn real gas flow in shale and production prediction by pore-scale modeling. Journal of Natural Gas Science and Engineering 28: 328-337, 2016
放射性废物防护中的输运（selected 5）
· Y.K. Yang and M. Wang*. Electrodiffusion of cations in compacted clay: a pore-scale view. Environmental Science & Technology 53(4): 1976-1984, 2019
· Y.K. Yang, R.A. Patel, S.V. Churakov*, N.I. Prasianakis, G. Kosakowski and M. Wang *. Multiscale modeling of ion diffusion in cement paste: electrical double layer effects. Cement and Concrete Composites 96: 55-65, 2019
· A. Alizadeh, X. Jin and M. Wang *. Pore-scale Study of Ion Transport Mechanisms in Inhomogeneously Charged Nanoporous Rocks: Impact of Interface Properties on Macroscopic Transport. Journal of Geophysical Research-Solid Earth 124: 017200, 2019
· Y.K. Yang, M. Wang *. Pore-scale study of thermal effects on ion diffusion in clay with inhomogeneous surface charge. Journal of Colloid and Interface Science 514: 443-451, 2018
· Y. Yang, X.T. He, M. Li and M. Wang *. Pore-scale modeling of chloride ionic diffusion in cement microstructures. Cement and Concrete Composites 85: 92-104, 2018
流-固、热-固耦合输运(selected 5)
· Z. Chen, X. Jin and M. Wang*. A new thermo-mechanical coupled DEM model with non-spherical grains for thermally induced damage of rocks. Journal of the Mechanics and Physics of Solids 116: 54-69, 2018
· Z. Chen, Z. Yang and M. Wang*. Hydro-mechanical coupled mechanisms of hydraulic fracture propagation in rocks with cemented natural fractures. Journal of Petroleum Science and Engineering 163: 421-434, 2018
· Z. Chen and M. Wang*. Pore-scale modeling of hydro-mechanical coupling mechanics in hydro-fracturing. Journal of Geophysical Research-Solid Earth 122: JB013989, 2017
· Z. Chen, C.Y. Xie, Y. Chen and M. Wang*. Bonding strength effects in hydro-mechanical coupling transport in granular porous media by pore-scale modeling. Computation 4: 15, 2016
· Y. Chen, Q. Kang, Q. Cai*, M. Wang*, D. Zhang. Lattice Boltzmann simulations of particle motion in binary immiscible fluids Communication in Computational Physics 18(3): 757-786, 2015
多相渗流(selected 5)
· C.Y. Xie, W. Lei, and M. Wang*. Lattice Boltzmann model for three-phase viscoelastic fluid flow. Physical Review E 97: 023312, 2018
· J. Zheng, Z. Chen, C.Y. Xie, Z. Wang, Z. Lei, Y. Ju and M. Wang*. Characterization of spontaneous imbibition dynamics in irregular pores by lattice Boltzmann modeling. Computers & Fluids 168: 21-31, 2018
· C.Y. Xie, A.Q. Raeini, Y. Wang, M. Blunt*, M. Wang*. An improved pore-network model with viscous coupling effect via direct simulation by lattice Boltzmann method. Advances in Water Resources. 100: 26-34, 2017
· C.Y. Xie, J. Zhang, V. Bertola, M. Wang*. Lattice Boltzmann Modeling for Multiphase Viscoplastic Fluid Flow. Journal of Non-Newton Fluid Mechanics 234: 118-128, 2016
· C.Y. Xie, J.Y. Zhang, V. Bertola and M. Wang*. Droplet evaporation on a horizontal substrate under gravity field by mesoscopic modeling. Journal of Colloid and Interface Science 463: 317-323, 2016
多尺度模拟算法(selected 5)
· Z.Y. Wang, M. Wang* S. Chen. Coupling of high-Knudsen and non-ideal gas effects in microporous media. Journal of Fluid Mechanics 840: 56-73, 2018
· Y.K. Yang, M. Wang*. Upscaling scheme for long-term ion electrodiffusion in microporous media. Physical Review E 96: 023308, 2017
· C.Y. Xie, A.Q. Raeini, Y. Wang, M. Blunt*, M. Wang*. An improved pore-network model with viscous coupling effect via direct simulation by lattice Boltzmann method. Advances in Water Resources. 100: 26-34, 2017
· G. Liu, J. Zhang and M. Wang*. Drop movements and replacement on surface driven by shear force via hybrid atomistic-continuum simulations. Molecular Simulation. 42(10): 855-862, 2016
· S. Chen*, M. Wang, and Z. Xia. Multiscale fluid mechanics and modeling. Procedia IUTAM 10: 100-114, 2014
格子Boltzmann算法(selected 5)
· Y. Guo, M. Wang*. Lattice Boltzmann modeling of phonon transport. Journal of Computational Physics 315: 1-15, 2016
· Y. Chen, Q. Cai, Z. Xia, M. Wang* and S. Chen. On the momentum exchange method in lattice Boltzmann simulations of particle-fluid interactions. Physical Review E. 88: 013303, 2013
· M. Wang*, and Q. Kang. Modeling electrokinetic flows in microchannels using coupled lattice Boltzmann methods. Journal of Computational Physics, 229: 728-744, 2010
· J. Wang, M. Wang, and Z. Li*. A Lattice Boltzmann Algorithm for Fluid-Solid Conjugate Heat Transfer. Inter. J. Thermal Sci. 46(3) 228-234, 2007
· M. Wang*, J. Wang, and S. Chen. Roughness and Cavitations effects on Electro-osmotic Flows in Rough Microchannels using the Lattice Poisson-Boltzmann Methods. Journal of Computational Physics. 226(1): 836-851, 2007