王圣凯
近期热点
资料介绍
个人简历
个人简介王圣凯的研究方向位于光学科学、热能工程、流体力学的前沿交叉点,具体包括开发高灵敏度激光传感器以及多物理量场精密激光光谱学测量方法,并将其应用于研究气体反应以及动力学过程,揭示其中的物理化学机制。 教育经历2012-2017, 博士: 斯坦福大学(Stanford University) 专业:机械工程2012-2017, 博士辅修:斯坦福大学(Stanford University) 专业:电气工程2010-2012, 硕士: 斯坦福大学(Stanford University) 专业:机械工程2006-2010, 学士: 北京大学 专业:理论与应用力学 主要科研工作经历2020-至今, 北京大学工学院,助理教授2016-2020, 美国斯坦福大学,高温气体动力学实验室,博士后 主要荣誉Bernard-Lewis Fellowship, 2016 PROFESSIONAL EXPERIENCE Feb. 2020-Present Assistant Professor at Dept. of Mechanics & Engineering Science, College of Engineering, Peking UniversityFeb. 2020-Present Co-PI at Beijing Innovation Center for Engineering Science and Advanced Technology, Peking University Oct. 2016-Feb. 2020 Postdoctoral Research Affiliate at High-Temperature Gasdynamics Laboratory (HTGL), Stanford University TEACHING & MENTORING Will co-teach Mathematical Analysis (Adavanced Calculus) with Prof. Yipeng SHI during 2020-2021. Teaching Assistant for Stanford graduate courses during 2015-2017: Chemeical Kinetics, Spectroscopy Lab. Mentored over 10 undergaduate/graduate students and visiting scholars at Stanford HTGL during 2012-2020. PROFESSIONAL MEMBERSHIPS Oct. 2018 - Present The American Institute of Aeronautics and AstronauticsSept. 2016 - Present The Optical SocietyFeb. 2016 - Present The International Society for Optics and PhotonicsJune 2014 - Present The Combustion InstituteBOOK CHAPTER S. Wang, D. F. Davidson, R. K. Hanson, Shock Tube Techniques for Kinetic Target Data to Improve Reaction Models, in Mathematical Modeling of Gas-Phase Complex Reaction Systems: Pyrolysis and Combustion, Eds. T. Faravelli, F. Manenti, E. Ranzi. Elsevier, 2019研究领域
主要研究方向高温气体的精密激光测量方法,燃烧学以及空气动力学的实验研究"RESEARCH FOCUS 1. Precision laser diagnostics for high-temperature gases 2. Experimental study of gas-phase reaction kinetics近期论文
主要论文列表Ding, Y., Wang, S.* and Hanson, R.K., Sensitive and interference-immune formaldehyde diagnostic for high-temperature reacting gases using two-color laser absorption near 5.6 µm. Combust. Flame, 2020; 213: 194-201.Clayman, N.E., Manumpil, M.A., Matson, B.D., Wang, S., Slavney, A.H., Sarangi, R., Karunadasa, H.I. and Waymouth, R.M.*, Reactivity of NO2 with Porous and Conductive Copper Azobispyridine Metallopolymers. Inorg. Chem., 2019; 58(16): 10856-10860.Wang, S.* and Hanson, R.K., Quantitative 2-D OH thermometry using spectrally resolved planar laser-induced fluorescence. Opt. Lett. 2019; 44(3): 578-581.Chao, X.*, Shen, G., Sun, K., Wang, Z., Meng, Q., Wang, S. and Hanson, R.K., Cavity-enhanced absorption spectroscopy for shocktubes: Design and optimization. Proc. Combust. Inst., 2019; 37(2): 1345-1353.Wang, S.*, Davidson, D.F. and Hanson, R.K., Shock tube measurements of OH concentration time-histories in benzene, toluene, ethylbenzene and xylene oxidation. Proc. Combust. Inst., 2019; 37(1): 163-170.Wei, W., Peng, W.Y., Wang, Y., Choudhary, R., Wang, S., Shao, J.* and Hanson, R.K., Demonstration of non-absorbing interference rejection using wavelength modulation spectroscopy in high-pressure shock tubes. Appl. Phys. B, 2019; 125(1): 9.Campbell, M.F.*, Wang, S., Davidson, D.F. and Hanson, R.K., Shock tube study of normal heptane first-stage ignition near 3.5 atm. Combust. Flame, 2018; 198: 376-392.Wang, S.* and Hanson, R.K., 2018. Ultra-sensitive spectroscopy of OH radical in high-temperature transient reactions. Opt. Lett. 2018; 43(15): 3518-3521.Shao, J., Zhu, Y., Wang, S., Davidson, D.F.* and Hanson, R.K., A shock tube study of jet fuel pyrolysis and ignition at elevated pressures and temperatures. Fuel, 2018; 226: 338-344.Xu, R., Wang, K., Banerjee, S., Shao, J., Parise, T., Zhu, Y., Wang, S., Movaghar, A., Lee, D.J., Zhao, R., Han, X., Gao, Y., Lu, T., Brezinsky, K., Egolfopoulos, F.N., Davidson, D.F., Hanson, R.K., Bowman, C.T., Wang, H.*, A physics-based approach to modeling real-fuel combustion chemistry–II. Reaction kinetic models of jet and rocket fuels. Combust. Flame, 2018; 193: 520-537.Wang, S.* and Hanson, R.K., High-sensitivity 308.6-nm laser absorption diagnostic optimized for OH measurement in shock tube combustion studies. Appl. Phys. B, 2018; 124(3): 37.Wang, S.*, Davidson, D.F. and Hanson, R.K., Shock tube and laser absorption study of CH2O oxidation via simultaneous measurements of OH and CO. J Phys. Chem. A, 2017; 121(45): 8561-8568.Wang, S.*, Parise, T., Johnson, S.E., Davidson, D.F. and Hanson, R.K., A new diagnostic for hydrocarbon fuels using 3.41-µm diode laser absorption. Combust. Flame, 2017; 186: 129-139.Wang, S.*, Davidson, D.F., Jeffries, J.B. and Hanson, R.K., Time-resolved sub-ppm CH3 detection in a shock tube using cavity-enhanced absorption spectroscopy with a ps-pulsed UV laser. Proc. Combust. Inst., 2017; 36(3): 4549-4556.Wang, S.*, Davidson, D.F. and Hanson, R.K., Rate constants of long, branched, and unsaturated aldehydes with OH at elevated temperatures. Proc. Combust. Inst., 2017; 36(1): 151-160.Nations, M.*, Wang, S., Goldenstein, C.S., Davidson, D.F. and Hanson, R.K., Kinetics of Excited Oxygen Formation in Shock-Heated O2–Ar Mixtures. J. Phys. Chem. A, 2016; 120(42): 8234-8243.Wang, S., Davidson, D.F.* and Hanson, R.K., Shock Tube measurement for the dissociation rate constant of acetaldehyde using sensitive CO diagnostics. J. Phys. Chem. A, 2016; 120(35): 6895-6901.Wang, S., Davidson, D.F.* and Hanson, R.K., Improved shock tube measurement of the CH4+ Ar= CH3+ H+ Ar rate constant using UV cavity-enhanced absorption spectroscopy of CH3. J. Phys. Chem. A, 2016; 120(28): 5427-5434.Wang, S.*, Sun, K., Davidson, D.F., Jeffries, J.B. and Hanson, R.K., Cavity-enhanced absorption spectroscopy with a ps-pulsed UV laser for sensitive, high-speed measurements in a shock tube. Opt. Express, 2016; 24(1): 308-318.Wang, S., Sun, K., Davidson, D.F.*, Jeffries, J.B. and Hanson, R.K., Shock-tube measurement of acetone dissociation using cavity-enhanced absorption spectroscopy of CO. J. Phys. Chem. A, 2015; 119(28): 7257-7262.Wang, S.*, Davidson, D.F. and Hanson, R.K., High temperature measurements for the rate constants of C1–C4 aldehydes with OH in a shock tube. Proc. Combust. Inst., 2015; 35(1): 473-480.Campbell, M.F.*, Wang, S., Goldenstein, C.S., Spearrin, R.M., Tulgestke, A.M., Zaczek, L.T., Davidson, D.F. and Hanson, R.K., Constrained reaction volume shock tube study of n-heptane oxidation: Ignition delay times and time-histories of multiple species and temperature. Proc. Combust. Inst., 2015; 35(1): 231-239.Nations, M.*, Wang, S., Goldenstein, C.S., Sun, K., Davidson, D.F., Jeffries, J.B. and Hanson, R.K., Shock-tube measurements of excited oxygen atoms using cavity-enhanced absorption spectroscopy. Appl. Opt. 2015; 54(29): 8766-8775.Wang, S., Li, S., Davidson, D.F.* and Hanson, R.K., Shock Tube Measurement of the High-Temperature Rate Constant for OH+ CH3→ Products. J. Phys. Chem. A, 2015; 119(33): 8799-8805.Sur, R.*, Wang, S., Sun, K., Davidson, D.F., Jeffries, J.B. and Hanson, R.K., High-sensitivity interference-free diagnostic for measurement of methane in shock tubes. J. Quant. Spectrosc. Radiat. Transf., 2015; 156: 80-87.Sun, K., Wang, S., Sur, R., Chao, X., Jeffries, J.B.* and Hanson, R.K., Time-resolved in situ detection of CO in a shock tube using cavity-enhanced absorption spectroscopy with a quantum-cascade laser near 4.6 µm. Opt. Express, 2014; 22(20): 24559-24565.Sun, K., Wang, S., Sur, R., Chao, X., Jeffries, J.B.* and Hanson, R.K., 2014. Sensitive and rapid laser diagnostic for shock tube kinetics studies using cavity-enhanced absorption spectroscopy. Opt. Express, 2014; 22(8): 9291-9300.Wang, S., Dames, E.E., Davidson, D.F.* and Hanson, R.K., Reaction rate constant of CH2O+ H= HCO+ H2 revisited: a combined study of direct shock tube measurement and transition state theory calculation. J. Phys. Chem. A, 2014; 118(44): 10201-10209.Xu, S., Thian, D., Wang, S., Wang, Y. and Prinz, F.B., Effects of size polydispersity on electron mobility in a two-dimensional quantum-dot superlattice. Phys. Rev. B, 2014; 90(14): 144202.Hong, Z., Lam, K.Y., Sur, R., Wang, S., Davidson, D.F.* and Hanson, R.K., On the rate constants of OH+ HO2 and HO2+ HO2: A comprehensive study of H2O2 thermal decomposition using multi-species laser absorption. Proc. Combust. Inst., 2013; 34(1): 565-571.Wang, S., Davidson, D.F.* and Hanson, R.K., High-temperature laser absorption diagnostics for CH2O and CH3CHO and their application to shock tube kinetic studies. Combust. Flame, 2013; 160(10): 1930-1938.Hanson, R.K., Pang, G.A., Chakraborty, S., Ren, W., Wang, S. and Davidson, D.F.*, Constrained reaction volume approach for studying chemical kinetics behind reflected shock waves. Combust. Flame, 2013; 160(9): 1550-1558.ACADEMIC SERVICES Reviewer for Optics Express, Journal of Quantitative Spectroscopy and Radiative Transfer, Applied Physics B, Combustion and Flame, Proceedings of the Combustion Institute, Fuel, Energy & Fuels, Combustion Science and Technology, Journal of Propulsion and Power, Journal of Thermo-physics and Heat Transfer, and Sensors. 相关热点