Dr. Shengkai Wang

JOURNAL PAPERS

1. Y Li*, S. Wang, C. L. Strand, R.K. Hanson. Two-temperature collisional-radiative modeling of partially ionized O2-Ar mixtures over 8000-10000K behind reflected shock waves. The Journal of Physical Chemistry A. 124 (2020), 3687-3697.
2. Y. Ding, S. Wang*, R. K. Hanson, Sensitive and interference-immune formaldehyde diagnostic for high-temperature reacting gases using two-color laser absorption near 5.6 µm, Combust. Flame, 213 (2020), 194-201.
3. N. E. Clayman, M. A. Manumpil, B. D. Matson, S. Wang, A. H. Slavney, R. Sarangi, H. I. Karunadasa, R. M. Waymouth*. Reactivity of NO2 with Porous and Conductive Copper Azobispyridine Metallopolymers. Inorg. Chem. 58 (2019), 10856-10860.
4. S. Wang*, R. K. Hanson, Quantitative 2-D OH thermometry using spectrally-resolved planar laser-induced fluorescence, Optics Letters, 44 (2019), 578-581.
5. X. Chao*, G. Shen, K. Sun, Z. Wang, Q. Meng, S. Wang, R. K. Hanson, Cavity-enhanced absorption spectroscopy for shock tubes: design and optimization, Proceedings of the Combustion Institute, 37 (2019), 1345-1353.
6. S. Wang*, D. F. Davidson, R. K. Hanson, Shock tube measurements of OH time-histories in benzene, toluene, ethylbenzene and xylene oxidation, Proceedings of the Combustion Institute, 37 (2019), 163-170.
7. W. Wei, W.Y. Peng, Y. Wang, R. Choudhary, S. Wang, J. Shao*, R. K. Hanson, Demonstration of non-absorbing interference rejection using wavelength modulation spectroscopy in high-pressure shock tubes. Applied Physics B, 125 (2019), 9.
8. M. F. Campbell*, S. Wang, D. F. Davidson, R. K. Hanson, Shock tube study of normal heptane first-stage ignition near 3.5 atm. Combustion and Flame, 198 (2018) 376-392.
9. S. Wang*, R. K. Hanson, Ultra-sensitive spectroscopy of OH radical in high-temperature transient reactions, Optics Letters, 43 (2018) 3518-3521.
10. J. Shao, Y. Zhu, S. Wang, D.F. Davidson*, R.K. Hanson, A shock tube study of jet fuel pyrolysis and ignition at elevated pressures and temperatures, Fuel, 226 (2018) 338-344.
11. R. Xu, K. Wang, S. Banerjee, J. Shao, T. Parise, Y. Zhu, S. Wang, A. Movaghar, D. J. Lee, R. Zhao, X. Han, Y. Gao, T. Lu, K. Brezinsky, F. N. Egolfopoulos, D. F. Davidson, R. K. Hanson, C. T. Bowman, H. Wang*, A physics-based approach to modeling real-fuel combustion chemistry - II. reaction kinetic models of jet and rocket fuels, Combustion and Flame, 193 (2018) 520-537.
12. S. Wang*, R. K. Hanson, High-sensitivity 308.6-nm laser absorption diagnostic optimized for OH measurement in shock tube combustion studies, Applied Physics B, 124 (2018) 37-43.
13. S. Wang*, D. F. Davidson, R. K. Hanson, A shock tube and laser absorption study of CH2O oxidation via simultaneous measurements of OH and CO, Journal of Physical Chemistry A, 121 (2017) 8561–8568.
14. S. Wang*, T. Parise, S. E. Johnson, D. F. Davidson, R. K. Hanson, A new diagnostic for hydrocarbon fuels using 3.41-m diode laser absorption, Combustion and Flame, 186 (2017), 129-139.
15. S. Wang*, D. F. Davidson, J. B. Jeffries, R. K. Hanson, Time-resolved sub-ppm CH3 detection in a shock tube using cavity-enhanced absorption spectroscopy with a ps-pulsed UV laser, Proceedings of the Combustion Institute, 36 (2017) 4549-4556.
16. S. Wang*, D. F. Davidson, R. K. Hanson, Shock tube measurements for the rate constants of long, branched, and unsaturated aldehydes with OH at elevated temperatures, Proceedings of the Combustion Institute, 36 (2017) 151-160.
17. M. Nations*, S. Wang, C. S. Goldenstein, D. F. Davidson, R. K. Hanson, Kinetics of Excited Oxygen Formation in Shock-Heated O2 − Ar Mixtures. Journal of Physical Chemistry A, 120 (2016) 8234-8243.
18. S. Wang*, D. F. Davidson, R. K. Hanson, Shock tube measurement for the dissociation rate constant of acetaldehyde using sensitive CO diagnostics, Journal of Physical Chemistry A, 120 (2016) 6895-6901.
19. S. Wang, D. F. Davidson*, R. K. Hanson, Improved shock tube measurement of the CH4 + Ar = CH3 + H + Ar rate constant using UV cavity-enhanced absorption spectroscopy of CH3, Journal of Physical Chemistry A, 120 (2016) 5427-5434.
20. S. Wang*, K. Sun, D. F. Davidson, J. B. Jefferies, R. K. Hanson, Cavity-enhanced absorption spectroscopy with a ps-pulsed UV laser for sensitive, high-speed measurements in a shock tube, Optics Express, 24 (2016) 308-318.
21. S. Wang, K. Sun, D. F. Davidson*, J. B. Jeffries, R. K. Hanson, Shock-tube measurement of acetone dissociation using cavity-enhanced absorption spectroscopy of CO. Journal of Physical Chemistry A, 119 (2015) 7257-7262.
22. S. Wang*, D. F. Davidson, R. K. Hanson, High temperature measurements for the rate constants of C1–C4 aldehydes with OH in a shock tube. Proceedings of the Combustion Institute, 35 (2015) 473-480.
23. M. F. Campbell*, S. Wang, C. S. Goldenstein, R. M. Spearrin, A. M. Tulgestke, L. T. Zaczek, D. F. Davidson, R. K. Hanson, Constrained reaction volume shock tube study of n-heptane oxidation: Ignition delay times and time-histories of multiple species and temperature. Proceedings of the Combustion Institute, 35 (2015) 231-239.
24. M. Nations*, S. Wang, C. S. Goldenstein, K. Sun, D. F. Davidson, J. B. Jefferies, R. K. Hanson, Shock-tube measurements of excited oxygen atoms using cavity-enhanced absorption spectroscopy, Applied Optics, 54 (2015) 8766-8775.
25. S. Wang, S. Li, D. F. Davidson*, R. K. Hanson, Shock tube measurement of the high-temperature rate constant for OH+ CH3→ products. Journal of Physical Chemistry A, 119 (2015) 8799-8805.
26. R. Sur*, S. Wang, K. Sun, D. F. Davidson, J. B. Jeffries, R. K. Hanson, High-sensitivity interference-free diagnostic for measurement of methane in shock tubes. Journal of Quantitative Spectroscopy and Radiative Transfer, 156 (2015) 80-87.
27. K. Sun, S. Wang, R. Sur, X. Chao, J. B. Jeffries*, R. K. Hanson, 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. Optics Express, 22 (2014) 24559-24565.
28. K. Sun, S. Wang, R. Sur, X. Chao, J. B. Jeffries*, R. K. Hanson, Sensitive and rapid laser diagnostic for shock tube kinetics studies using cavity-enhanced absorption spectroscopy. Optics Express, 22 (2014) 9291-9300.
29. S. Wang, E. E. Dames, D. F. Davidson*, R. K. Hanson, Reaction rate constant of CH2O+ H= HCO+ H2 revisited: A combined study of direct shock tube measurement and transition state theory calculation. Journal of Physical Chemistry A, 118 (2014) 10201-10209.
30. S. Xu, D. Thian, S. Wang, Y. Wang, F. B. Prinz*, Effects of size polydispersity on electron mobility in a two-dimensional quantum-dot superlattice. Physics Review B, 90 (2014) 144202.
31. Z. Hong, K. Y. Lam, R. Sur, S. Wang, D. F. Davidson*, R. K. Hanson, On the rate constants of OH+ HO2 and HO2+ HO2: A comprehensive study of H2O2 thermal decomposition using multi-species laser absorption. Proceedings of the Combustion Institute, 34 (2013) 565-571.
32. S. Wang, D. F. Davidson*, R. K. Hanson, R. K. High-temperature laser absorption diagnostics for CH2O and CH3CHO and their application to shock tube kinetic studies. Combustion and Flame, 160 (2013) 1930-1938.
33. R. K. Hanson, G. A. Pang, S. Chakraborty, W. Ren, S. Wang, D. F. Davidson*, Constrained reaction volume approach for studying chemical kinetics behind reflected shock waves. Combustion and Flame, 160 (2013) 1550-1558.

CONFERENCE PAPERS

1. A. J. Susa, S. Wang, D. F. Davidson, R. K. Hanson, Time-Resolved Speciation of iso-Octane First-Stage Ignition Products at Elevated Effective Pressures in a Shock Tube, US 11th National Combustion Meeting, 2019
2. S. Wang, C. L. Strand, R. K. Hanson, Spectrally-Resolved Absorption and Laser-Induced Fluorescence of High-Temperature Gases, AIAA SciTech Forum, 2019
3. J. Streicher, A. Krish, S. Wang, D. F. Davidson, R. K. Hanson, Measurements of Oxygen Vibrational Relaxation and Dissociation Using Ultraviolet Laser Absorption in Shock Tube Experiments, AIAA SciTech Forum, 2019
4. S. Wang, D. F. Davidson, R. K. Hanson, A shock tube study of CH2O oxidation via simultaneous laser absorption measurements of CO and OH, 10th International Conference on Chemical Kinetics, 2017
5. S. Wang, T. Parise, D. F. Davidson, R. K. Hanson, A new diagnostic for hydrocarbon fuels using 3.41-m diode laser absorption, US 10th National Combustion Meeting, 2017
6. J. Shao, Y. Zhu, S. Wang, D. F. Davidson, R. K. Hanson, Shock Tube Study of Jet Fuel Pyrolysis and Ignition at Elevated Pressure, US 10th National Combustion Meeting, 2017
7. R. Xu, D. Chen, K. Wang, Y. Tao, J. K. Shao, T. Parise, Y. Zhu, S. Wang, R. Zhao, D. J. Lee, F. N. Egolfopoulos. HyChem Model: Application to Petroleum-Derived Jet Fuels. US 10th National Combustion Meeting, 2017
8. D. F. Davidson, Y. Zhu, S. Wang, T. Parise, R. Sur, R. K. Hanson, Shock Tube Measurements of Jet and Rocket Fuels, 54th AIAA Aerospace Sciences Meeting, 2016
9. Y. Zhu, S. Wang, D. F. Davidson, R. K. Hanson, Shock Tube Measurements of Species Time-Histories during Jet Fuel Pyrolysis and Oxidation, 25th International Colloquium on the Dynamics of Explosions and Reactive Systems, 2015
10. Y. Zhu, S. Wang, R. K. Hanson, D. F. Davidson, Shock Tube/Laser Absorption Measurements of Jet Fuel Pyrolysis and Oxidation, 53rd AIAA Aerospace Sciences Meeting, 2015
11. D. F. Davidson, A. Tulgestke. Y. Zhu, S. Wang, R. K. Hanson, Species Time-History Measurements during Jet Fuel Pyrolysis, 30th International Symposium on Shock Waves, 2015
12. S. Wang, D. F. Davidson, R. K. Hanson, Laser Absorption Diagnostics for Aldehydes in Shock Tube Kinetics Studies, 29th International Symposium on Shock Waves, 2013
13. R. K. Hanson, S. Chakraborty, G. A. Pang, W. Ren, S. Wang, D. F. Davidson, Constrained Reaction Volume: A New Approach to Studying Reactive Systems in Shock Tubes, 29th International Symposium on Shock Waves, 2013
14. R. K. Hanson, S. Chakraborty, G. A. Pang, W. Ren, S. Wang, D. F. Davidson, Constrained Reaction Volume: A Strategy for Reflected Shock Wave Kinetics Experiments, 24th International Colloquium on the Dynamics of Explosions and Reactive Systems, 2013
15. K. Y. Lam, D. Vinh, S. Wang, Z. Hong, D. F. Davidson and R. K. Hanson, Shock Tube Ignition Delay Time Measurements of Propane/O2/Ar Mixtures at Near-Constant-Volume Conditions, WSS/CI 2009 Fall Meeting, 2009

BOOK CHAPTER

1. 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