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个人简介

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

研究领域

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

近期论文

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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.

学术兼职

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.

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