马维刚，甘肃环县人，清华大学航天航空学院副教授，博士生导师。本科生《热物理量测技术》主讲教师。曾获国际传热传质中心Hartnett-Irvine Award（2018）、亚洲热物性研究青年科学家奖（2019）、教育部自然科学一等奖（2018）、清华大学大学生研究训练计划优秀指导教师一等奖（2016）等荣誉。主要研究领域为微纳尺度传热、热物性，能量高效转换与存储，高温高压超临界混合工质热物性，主持国家自然科学基金、教育部联合研究基金、清华大学自主科研计划、北京卫星环境工程研究所创新基金、博士后基金面上一等资助和特别资助等多项项目，作为学术骨干参加国家重点研发计划项目、国家自然科学基金重大项目、重点项目和仪器设备专项等，发表SCI论文50余篇。现任中国工程热物理学会传热传质青年委员会秘书、北京热物理与能源工程学会青年委员会委员。担任《Journal of Thermal Science》学科编辑。
联系方式：， Email：maweigang@tsinghua.edu.cn

教育背景2002年9月—2006年7月，清华大学航天航空学院，获工学学士学位；
2006年9月—2012年1月，清华大学航天航空学院，获工学博士学位；

工作履历2012年1月—2013年12月，清华大学航天航空学院 博士后；
2012年4月—2012年7月，日本九州大学 访问；
2013年12月—2014年12月，清华大学航天航空学院 讲师；
2014年12月—至今，清华大学航天航空学院 副教授。
研究领域微纳尺度传热；
微纳米材料热物性；
能量高效转换与存储；
高温高压超临界混合工质热物性。
研究概况主要从事微纳尺度传热、热物性，能量高效转换与存储，高温高压超临界混合工质热物性的研究工作。主持国家自然科学基金、教育部联合研究基金、清华大学自主科研计划、北京卫星环境工程研究所创新基金、博士后基金面上一等资助和特别资助等多项项目，作为学术骨干参加国家重点研发计划项目、国家自然科学基金重大项目、重点项目和仪器设备专项等。发表SCI论文50余篇，应邀做国际学术会议特邀报告7次，中国工程热物理学会传热传质学术会议主旨报告和特邀报告各1次，获国际传热传质中心Hartnett-Irvine Award（2018）、亚洲热物性研究青年科学家奖（2019）、教育部自然科学一等奖（2018）、清华大学大学生研究训练计划优秀指导教师一等奖（2016），第三届国际传热论坛“Best Presentation Award” (2012)。担任《Journal of Thermal Science》学科编辑，《Applied Thermal Engineering》专刊客座编辑，第16届国际传热大会副编辑，第15届国际传热大会分会场主席，第6和第7届国际微纳技术会议学术委员会委员，第1和第2届国际热科学与工程测量技术研讨会组委会委员，2019年传热与能源国际青年研讨会秘书长。
奖励与荣誉[1] 2019，亚洲热物性研究青年科学家奖
[2] 2018，国际传热传质中心Hartnett-Irvine Award
[2] 2018，教育部自然科学奖一等奖
[3] 2016，清华大学大学生研究训练计划优秀指导教师一等奖
[4] 2012，第三届国际传热论坛“Best Presentation Award”

学术成果发表SCI论文50余篇，应邀做国际学术会议特邀报告7次，中国工程热物理学会传热传质学术会议主旨报告和特邀报告各1次。
[1]Zhang Y F, Fan A R, Luo S T, Wang H D, Ma W G, Zhang X, Suspended 2D anisotropic materials thermal diffusivity measurements using dual-wavelength flash Raman mapping method, International Journal of Heat and Mass Transfer, 145:118795, 2019.
[2]Fan A R, Hu Y D, Wang H D, Ma W G, Zhang X, Dual-wavelength flash Raman mapping method for measuring thermal diffusivity of suspended 2D nanomaterials, International Journal of Heat and Mass Transfer, 143:118460, 2019.
[3]Song D X, Ma W G*, Zhang X, Thermal conductivity in highly loaded metallic nanowire-dielectric composite: Effect of percolation network, Chemical Physics Letters, 731: 136630, 2019.
[4]Song D X, Zhang Y F, Ma W G*, Zhang X, Role of electron–phonon coupling in thermal conductivity of metallic nanofluids, Journal of Physics D: Applied Physics 52: 485302, 2019.
[5]Cheng S Y, Shang F, Ma W G, et al., Density Measurements of the H-2-CO2-CH4-CO-H2O System by the Isochoric Method at 722-930 K and 15.4-30.3 MPa, Journal of Chemical and Engineering Data, 64:4024-4036, 2019.
[6]Li F Y, Shi S Y, Ma W G, Zhang X, A switched vibrating-hot-wire method for measuring the viscosity and thermal conductivity of liquids, Review of Scientific Instruments, 90:075105, 2019.
[7]Wu J C, An M, Ma W G, Spontaneous rectification and absolute negative mobility of inertial Brownian particles induced by Gaussian potentials in steady laminar flows, Soft Matter, 15:7187-7194, 2019.
[8]Fan A R, Li Q Y, Ma W G, Zhang X, Laser flash Raman spectroscopy method for characterizing the specific heat of a single nanoparticle, Journal of Nanoscience and Nanotechnology, 19: 7004-7013, 2019.
[9]Song D X, Ma W G*, Zhang X, Anisotropic thermal conductivity in ferrofluids induced by uniform cluster orientation and anisotropic phonon mean free path, International Journal of Heat and Mass Transfer, 138:1228-1237, 2019.
[10]Wang X Q, Shi S Y, Qi X, Wu D, Ma W G*, Zhang X, Thermoelectric properties of single crystal EuBiSe3 fiber, Nanoscale and Microscale Thermophysical Engineering, 23:200-210, 2019.
[11]Zhang G, Duan Z, Qi X, Xu Y T, Li L, Ma W G, Zhang H, Liu C H, Yao W, Harvesting environment energy from water-evaporation over free-standing graphene oxide sponges, Carbon, 148:1-8, 2019.
[12]Zhang C, Jin C Z, Teng G X, Gu Y N, Ma W G*, Controllable synthesis of hollow MnFe2O4 by self-etching and its application in high-performance anode for lithium-ion batteries, Chemical Engineering Journal, 365:121-131, 2019.
[13]Jin C Z, Teng G X, Gu Y A, Cheng H, Fu S P, Zhang C, Ma W G*, Functionalized hollow MnFe2O4 nanospheres: design, applications and mechanism for efficient adsorption of heavy metal ions, New Journal of Chemistry, 43:5879-5889, 2019.
[14]Liu J H, Liu H, Ma W G, Zhang X, Non-contact T-type Raman method for measurement of thermophysical properties of micro-/nanowires, Review of Scientific Instruments, 90:044901, 2019.
[15]Cheng S Y, Shang F, Ma W G, Jin H, Sakoda N, Zhang X, Guo L J, Density data of two (H2 + CO2) Mixtures and a (H2 + CO2 + CH4) mixture by a modified Burnett method at temperature 673 K and pressures up to 25 MPa, Journal of Chemical and Engineering Data, 64:1693-1704, 2019.
[16]Fan A R, Hu Y D, Ma W G, Wang H D, Zhang X, Dual-wavelength laser flash Raman spectroscopy method for in-situ measurements of the thermal diffusivity: principle and experimental verification, Journal of Thermal Science, 28:159-168, 2019.
[17]Song D X, Jing D W, Ma W G*, et al., Effect of particle aggregation on thermal conductivity of nanofluids: Enhancement of phonon MFP, Journal of Applied Physics, 125:015103, 2019.
[18]Miao T T, Yu D W, Xing L, Li D W, Jiao L Y, Ma W G*, Zhang X, Current rectification in a structure: ReSe2/Au contacts on both sides of ReSe2, Nanoscale Research Letters, 14(1):1, 2019.
[19]Song D X, Ma W G*, Zhang X, Lattice thermal conductivity of Si/Ge composite thermoelectric material: Effect of Si particle distribution, International Journal of Energy Research, 43(1):379-390, 2019.
[20]Song D X, Jing D W, Ma W G*, et al., High thermal conductivity of nanoparticles not necessarily contributing more to nanofluids, Applied Physics Letters, 113: 223104, 2018.
[21]Qi X, Ma W G*, Zhang X, et al., Raman characterization and transport properties of morphology-dependent two-dimensional Bi2Te3 nanofilms, Applied Surface Science, 451: 41-48, 2018.
[22]Shi X G, Li M Y, Ma W G, et al., Experimental study on thermal transport property of KD-II SiC fiber, Journal of Inorganic Materials, 33:756-760, 2019.
[23]Ma W G, Shi S Y, Zhang Xing , Three-wire method to characterize the thermoelectric properties of one-dimensional materials , Journal of Vacuum Science and Technology B, 36: 022903, 2018.
[24]Cheng S Y, Shi X G, Ma W G, et al., Experimental research on thermal transport properties of crystallized palladium-based alloys, Frontiers In Energy, 12:121-126, 2018.
[25]Ma W G, Liu Y J, Yan S et al., Chemically doped macroscopic graphene fibers with significantly enhanced thermoelectric properties, Nano Research, 11(2):741-750, 2018.
[26]Miao T T, Li D W, Shi S Y, Ji Z L, Ma W G*, Zhang X, Zhong Q, Wang X S, Essential role of enhanced surface electron–phonon interactions on the electrical transport of suspended polycrystalline gold nanofilms, RSC Advances, 8(37): 20679-20685, 2018.
[27]Dong C, Ma W G*, Zhang X, Modulation of the time-domain reflectance signal induced by thermal transport and acoustic waves in multilayered structure, International Journal of Heat and Mass Transfer, 114: 915~922, 2017.
[28]Shi X G, Cheng S Y, Ma W G, et al., Experimental research on thermal transport properties of palladium-based amorphous alloys, Journal of Non-Crystalline Solids, 458: 157-161, 2017.
[29]Yan S, Dong C, Miao T T, Wang W, Ma W G*, Zhang X, Kohno M, Takata Y, Long delay time study of thermal transport and thermal stress in thin Pt film-glass substrate system by time-domain thermoreflectance measurements, Applied Thermal Engineering, 111: 1433-1440, 2017.
[30]Ma W G, Liu Y J, Yan S, Miao T T, Shi S Y, Yang M C, Zhang X, Gao C. Systematic characterization of transport and thermoelectric properties of a macroscopic graphene fiber, Nano Research, 9(11): 3536-3546, 2016.
[31]Miao T T, Shi S Y, Yan S, Ma W G*, Zhang X, Takahashi K, Ikuta T, Integrative characterization of the thermoelectric performance of an individual multiwalled carbon nanotube, Journal of Applied Physics, 120: 124302, 2016.
[32]Li Q Y, Ma W G, Zhang X, Laser flash Raman spectroscopy method for characterizing thermal diffusivity of supported 2d nanomaterials, International Journal of Heat and Mass Transfer, 95:956-963, 2016.
[33]Miao T T, Ma W G*, Yan S, Zhang X, Kohno M, Takata Y, Ikoma Y, Thermal transport and thermal stress in a molybdenum film-glass substrate system, Journal of Vacuum Science and Technology B, 34: 021801, 2016.
[34]Ma W G, Miao T T, Zhang X, et al, A t-type method for characterization of the thermoelectric performance of an individual free-standing single crystal Bi2S3 nanowire, Nanoscale, 8(5):2704-2710, 2016.
[35]Liu J H, Wang H D, Hu Y D, Ma W G, Zhang X, Measurement of apparent thermal conductivity and laser absorptivity of individual carbon fibers, International Journal of Thermophysics, 36:2740-2747, 2015.
[36]Miao T T, Ma W G*, Zhang X, Novel ac heating-dc detection method for active thermoelectric scanning thermal microscopy, International Journal of Thermophysics, 36(10-11):2599-2608, 2015.
[37]Ma W G, Miao T T, Zhang X, et al, Comprehensive study of thermal transport and coherent acoustic-phonon wave propagation in thin metal film-substrate by applying picosecond laser pump-probe method, Journal of Physical Chemistry C, 119(9):5152-5159, 2015.
[38]Liu J H, Wang H D, Hu Y D, Ma W G, Zhang X, Laser flash-Raman spectroscopy method for the measurement of the thermal properties of micro/nano wires, Review of Scientific Instruments, 86:014901, 2015.
[39]Ma W G, Miao T T, Zhang X, et al, Thermal performance of vertically-aligned multi-walled carbon nanotube array grown on platinum film, Carbon, 77:266-274, 2014.
[40]Jia L, Ma W G, Zhang X, Ultrafast carrier dynamics in polycrystalline bismuth telluride nanofilm, Applied Physics Letters, 104:241911, 2014.
[41]Shao H Y, Ma W G, Kohno M, et al, Hydrogen storage and thermal conductivity properties of mg-based materials with different structures, International Journal of Hydrogen Energy, 39(18):9893-9898, 2014.
[42]Miao T T, Ma W G, Zhang X, et al, Study on the cross plane thermal transport of polycrystalline molybdenum nanofilms by applying picosecond laser transient thermoreflectance method, Journal of Nanomaterials, 2014:578758, 2014.
[43]Ma W G, Wang H D, Zhang X, et al, Study of the electron-phonon relaxation in thin metal films using transient thermoreflectance technique, International Journal of Thermophysics, 34(12):2400-2415, 2013.
[44]Liu J H, Wang H D, Ma W G, et al, Simultaneous measurement of thermal conductivity and thermal contact resistance of individual carbon fibers using Raman spectroscopy, Review of Scientific Instruments, 84:044901, 2013.
[45]Ma W G, Zhang X, Study of the thermal, electrical and thermoelectric properties of metallic nanofilms, International Journal of Heat and Mass Transfer, 58(1-2):639-651, 2013.
[46]Miao T T, Ma W G, Zhang X, et al, Significantly enhanced thermoelectric properties of ultralong double-walled carbon nanotube bundle, Applied Physics Letters, 102:053105, 2013.
[47]Miao T T, Ma W G, Zhang X, Ac heating-dc detecting method for Seebeck coefficient measurement of the thermoelectric micro/nano devices, Journal of Vacuum Science and Technology B, 30:051804, 2012.
[48]Ma W G, Wang H D, Zhang X, et al, Theoretical and experimental study of femtosecond pulse laser heating on thin metal film, Acta Physica Sinica, 60:064401, 2011.
[49]Miao T T, Song M X, Ma W G, et al, Theoretical calculations of thermophysical properties of single-wall carbon nanotube bundles, Chinese Physics B, 20:056501, 2011.
[50]Wang H D, Ma W G, Guo Z Y, et al, Measurements of electron-phonon coupling factor and interfacial thermal resistance of metallic nano-films using a transient thermoreflectance technique, Chinese Physics B, 20:040701, 2011.
[51]Miao T T, Ma W G, Zhang X, et al, A self-heating 2 omega method for Seebeck coefficient measurement of thermoelectric materials, Review of Scientific Instruments, 82:024901, 2011.
[52]Wang H D, Ma W G, Zhang X, et al, Theoretical and experimental study on the heat transport in metallic nanofilms heated by ultra-short pulsed laser, International Journal of Heat and Mass Transfer, 54(4):967-974, 2011.
[53]Ma W G, Zhang X, Takahashi K, Electrical properties and reduced Debye temperature of polycrystalline thin gold films, Journal of Physics D, 43:465301, 2010.
[54]Ma W G, Wang H D, Zhang X, et al, Experiment study of the size effects on electron-phonon relaxation and electrical resistivity of polycrystalline thin gold films, Journal of Applied Physics, 108:064308, 2010.
[55]Wang H D, Ma W G, Zhang X, et al, Measurement of the thermal wave in metal films using femtosecond laser thermoreflectance system, Acta Physica Sinica, 59(6):3856-3862, 2010.
[56]Feng B, Ma W G, Li Z X, et al, Simultaneous measurements of the specific heat and thermal conductivity of suspended thin samples by transient electrothermal method, Review of Scientific Instruments, 80:064901, 2009.
[57]Ma W G, Wang H D, Zhang X, et al, Different effects of grain boundary scattering on charge and heat transport in polycrystalline platinum and gold nanofilms, Chinese Physics B, 18(5):2035-2040, 2009.
[58]Wang J L, Gu M, Ma W G, et al, Temperature dependence of the thermal conductivity of individual pitch-derived carbon fibers, New Carbon Materials, 23(3):259-263, 2008.