个人简历

2013年获上海交通大学机械工程学士学位，2017年获德州农工大学机械工程博士学位，2017-2019年进入美国圣路易斯华盛顿大学机械工程与材料科学方向进行博士后研究。专业方向为传热学、工程热力学及流体力学。
Binjian Ma received the B.S. degree in mechanical engineering from Shanghai Jiao Tong University, Shanghai, China, in 2013 and the Ph.D. degree in mechanical engineering from Texas A&M University, College Station, TX, USA in 2017. From 2013 to 2017, he was a Research Assistant with the Multiphase Flow & Heat Transfer Laboratory at Texas A&M University. Afterwards, he worked as a Postdoctoral Research Associated with the Nanoscale Interfacial Transport Laboratory at Washington University in St. Louis from 2017 to 2019. Since March 2020, he has been an Assistant Professor with the Department of Mechanical Engineering & Automation at Harbin Institute of Technology (Shenzhen) in Guangdong, China. He has authored 13 articles (8 journal articles) and one book chapter. His research interests include multiphase flow and heat transfer, phase change process and application, nanofluids, thermal management of electronics, and thermal energy storage system.
教育背景
09/2009 －08/2013 上海交通大学机械工程专业 本科
09/2013 －08/2017 德州农工大学机械工程专业 博士
科研工作经历
09/2017 －08/2019 圣路易斯华盛顿大学 博士后研究员
03/2020 - 至今 哈尔滨工业大学(深圳) 助理教授
科研项目
2021 - 2022 (主持) 深圳市高等院校稳定支持面上项目：薄膜蒸发在高热流密度系统中的热管理应用和传热传质机理探究
2020 - 2022 (主持) 哈工大（深圳）新教师科研启动项目：高长径比微纳结构上的薄膜蒸发相变传热传质特征
2019 - 2020 (参与) Development of an Evaporative Microheat Exchanger Using an Array of Porous Micropillar Structures, funded by Google Inc.
2017 - 2020 (参与) Thermal and Electrical Co-Optimization for Power Management of High-Powered Semiconductor Devices, funded by Cisco System
2019 - 2020 (参与) Nanoscale Energy and Interfacial Transport Research Based Mentoring Program to increase Underrepresented Minority Students in STEM, funded by NSF BPE
2014 - 2017 (参与) Molten Salt Nanofluids: Investigation of Thermophysical Properties for Enhanced Thermal Energy Storage (TES) and Heat Transfer Fluids (HTF), funded by General Electric (previously Alstom Energy)
学术报告
1) Li, J., Wu, H., Ma, B., Shan, L., Padilla, J., and Agonafer, D., “Geometric optimization of a microdroplet for enhanced evaporative heat transfer”, ASME Summer Heat Transfer Conference, Bellevue, WA, July 2019
2) Ma, B., Zhou, R., Shan, L., Dogruoz, B., and Agonafer, D., “Molecular Dynamic Simulation of Evaporative Heat Transfer on Graphene Coated Silicon Substrate for Electronics Cooling”, IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm), Las Vegas, NV, May 2019
3) Shan, L., Ma, B., Dogruoz, B., and Agonafer, D., “Experimental and Numerical Investigation of Microdroplets Evaporating on Porous Micropillar Structures”, SEMI-Therm 35th Annual Symposium, San Jose, CA, March 2019
4) Ma, B., Shan, Li., Dogruoz, B., and Agonafer, D., “Molecular dynamics Simulation of Thin-Film Evaporation from Nanocoated Surfaces: An Investigation of the Role of Surface Wettability Interfacial thermal resistance on the Evaporate Rate”, International Mechanical Engineering Congress and Exposition (IMECE), Pittsburgh, PA, November 2018
5) Shan, L., Ma, B., Dogruoz, B., and Agonafer, D., “Fundamental Mechanisms of Evaporation Kinetics of Non-Spherical Microdroplets Confined by Asymmetric Micropillar Structures”, International Mechanical Engineering Congress and Exposition (IMECE), Pittsburgh, PA, November 2018
6) Shan, L., Ma, B., Shuai, S., Dogruoz, B., and Agonafer, D., “Experimental Investigation of Microdroplet Evaporation on a Porous Micropillar Structure”, International Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic Microsystems (InterPACK), San Francisco, CA, August 2018.
7) Shuai, S., Shan, L., Ma, B., Du, Z., Dogruoz, B., and Agonafer, D., “Numerical Investigation of Shape Effect on Microdroplet Evaporation”, International Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic Microsystems (InterPACK), San Francisco, CA, August 2018.
8) Ma, B., Kumar, N., Kuchibhotla, A. and Banerjee, D., “Estimation of Measurement Uncertainties for Thermal Conductivity of Nanofluids using Transient Plane Source (TPS) Technique”, IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm), San Diego, CA, May 2018
9) Ma, B., Kumar, N., Kuchibhotla, A. and Banerjee, D., “Experimental Measurement of the Effect of Particle Concentration on the Specific Heat Capacity of Silica Nanofluids”, IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm), San Diego, CA, May 2018
10) Ma, B., and Banerjee, D., “Study of nucleation and growth during in-situ synthesis of nanoparticles in a liquid environment”, ASME Summer Heat Transfer Conference, Bellevue, WA, July 2017
11) Ma, B., and Banerjee, D., “A Novel Percolation Model for the Numerical Prediction of Heat Conduction in a Nanofluid with Porous Nanostructure”, ASME Summer Heat Transfer Conference, Bellevue, WA, July 2017
12) Ma, B., and Banerjee, D., “Exploring the “Nano-Fin Effect” in pool boiling enhancement on “large” horizontal heaters using temperature nano-sensor arrays”, Micro & Nanoscale Phase Change Heat Transfer, Gordon Research Conference, Galveston, TX, Jan 2017.
13) Ma, B., and Banerjee, D., “Study of molten salt nanomaterials for Thermal Energy Storage (TES) and Heat Transfer Fluid (HTF) applications”, ASME Summer Heat Transfer Conference, Washington DC, July 2016.
14) Tamakuwala, H.D., Ma, B., and Banerjee, D., “Experimental Investigation of Corrosivity of Molten Salt Nanomaterials for Applications in Concentrated Solar Power as Thermal Energy Storage (TES) and Het Transfer Fluids (HTF)”, ASME Summer Heat Transfer Conference, Washington DC, July 2016
15) Roy, R, Ma, B., and Banerjee, D., “Experimental study of nano-Fin Effect (nFE) in Nucleate Boiling using AAO Nanofins”, ASME Summer Heat Transfer Conference, Washington DC, July 2016
16) Ma, B., and Banerjee, D., “Study of molten salt nanomaterials for Thermal Energy Storage (TES) and Heat Transfer Fluid (HTF) applications”, ASME International Mechanical Engineering Congress & Exposition (IMECE), Houston, TX, Nov 2015.
17) Ma, B., and Banerjee, D., “Design of Molten Salt Heat Transfer Loop Facility”, ASME International Mechanical Engineering Congress & Exposition (IMECE), Houston, TX, Nov 2015.
18) Ma, B., and Banerjee, D., \

研究领域

多相流传热传质、相变传热、纳米流体、热管理技术、热能储存等。""

近期论文

Ma, B.*, Shin, D. and Banerjee, D. (2021) One-step synthesis of molten salt nanofluid for thermal energy storage application – a comprehensive analysis on thermophysical property, corrosion behavior, and economic benefit. Journal of Energy Storage, 35, p. 102278.
Ma, B.*, Shin, D. and Banerjee, D. (2020) Synthesis and characterization of molten salt nanofluids for thermal energy storage application in concentrated solar power plants – mechanistic understanding of specific heat capacity enhancement. Nanomaterials, 10(11):2266.
Ma, B.* (2020) Analysis of Capillary Flow in a Parallel Microchannel-Based Wick Structure with Circular and Noncircular Geometries. Langmuir, 36(45), pp. 13485-13497
Ma, B., Shan, L., Dogruoz, M.B. and Agonafer, D.* (2019) Evolution of Microdroplet Morphology Confined on Asymmetric Micropillar Structures. Langmuir, 35(37), pp. 12264-12275.
Ma, B.* and Banerjee, D. (2019) Numerical modeling of nanofluid thermal conductivity: the effect of nano-network on thermal transport behavior. Journal of Heat Transfer, 141(12), p. 122401.
Shan, L., Ma, B., Li, J., Dogruoz, B. and Agonafer, D.* (2019) Investigation of the evaporation heat transfer mechanism of a non-axisymmetric droplet confined on a heated micropillar structure. International Journal of Heat and Mass Transfer, 141, pp.191-203.
Shan, L., Shuai, S., Ma, B., Du, Z., Dogruoz, B. and Agonafer, D.* (2019) Numerical investigation of shape effect on microdroplet evaporation. Journal of Electronic Packaging, 141(4), pp. 041008.
Shan, L., Li, J., Ma, B., Jiang, X., Dogruoz, B. and Agonafer, D.* (2019) Experimental investigation of evaporation from asymmetric microdroplets confined on heated micropillar structures. Experimental Thermal and Fluid Science, 109, p.109889.
Li, J., Shan, L., Ma, B., Jiang, X., Solomon, A., Iyengar, M., Padilla, J. and Agonafer, D.* (2019) Investigation of the confinement effect on the evaporation behavior of a droplet pinned on a micropillar structure. Journal of colloid and interface science, 555, pp.583-594.
Agonafer, D.D.*, Lee, H., Vasquez, P.A., Won, Y., Jung, K.W., Lingamneni, S., Ma, B., Shan, L., Shuai, S., Du, Z., Maitra, T., Palko, J.W. and Goodson, K. E. (2018) Porous micropillar structures for retaining low surface tension liquids. Journal of colloid and interface science, 514, pp.316-327.
Ma, B.* and Banerjee, D. (2017) Experimental measurements of thermal conductivity of alumina nanofluid synthesized in salt melt. AIP Advances, 7(11), p.115124.
著作
Ma, B. and Banerjee, D., 2018. A review of nanofluid synthesis. In Advances in Nanomaterials (pp. 135-176). Springer, Cham.
会议论文
Ma, B., Shan, L., Li, J., Dogruoz, B. and Agonafer, D., 2019, May. Molecular Dynamic Simulation of the Effect of Nanocoating on Two-Phase Evaporative Heat and Mass Transfer. In 2019 18th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm) (pp. 226-231). IEEE.
Shuai, S., Du, Z., Ma, B., Shan, L., Dogruoz, B. and Agonafer, D., 2018, November. Numerical investigation of shape effect on microdroplet evaporation. In ASME 2018 International Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic Microsystems (InterPack). ASME Digital Collection.
Ma, B., Kumar, N., Kuchibhotla, A. and Banerjee, D., 2018, May. Experimental Measurement of the Effect of Particle Concentration on the Specific Heat Capacity of Silica Nanofluids. In 2018 17th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm) (pp. 246-251). IEEE.
Ma, B., Kumar, N., Kuchibhotla, A. and Banerjee, D., 2018, May. Estimation of Measurement Uncertainties for Thermal Conductivity of Nanofluids using Transient Plane Source (TPS) Technique. In 2018 17th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm) (pp. 178-186). IEEE.
Ma, B. and Banerjee, D., 2017, October. Predicting Particle Size Distribution in Nanofluid Synthesis. In ASME 2017 Heat Transfer Summer Conference. ASME Digital Collection.
2016年-至今，美国机械工程师学会 (ASME)会员；
2016年-至今，电气和电子工程师协会 (IEEE)会员；
ASME 2018 InterPACK 分会主席