Our websites may use cookies to personalize and enhance your experience. By continuing without changing your cookie settings, you agree to this collection. For more information, please see our University Websites Privacy Notice.

Chemical Kinetics Investigation Using Rapid Compression Machines

Chemical Kinetics Investigation Using Rapid Compression Machine

G. Mittal and C. J. Sung, “Aerodynamics inside a Rapid Compression Machine,” Combustion and Flame 145, 160-180 (2006).
G. Mittal, C. J. Sung, and R. A. Yetter, “Autoignition of H₂/CO at Elevated Pressures in a Rapid Compression Machine,” International Journal of Chemical Kinetics 38, 516-529 (2006).
G. Mittal and C. J. Sung, “A Rapid Compression Machine for Chemical Kinetics Studies at Elevated Pressures and Temperatures,” Combustion Science and Technology 179 (3), 497-530 (2007).
G. Mittal, C. J. Sung, M. Fairweather, A. S. Tomlin, J. F. Griffiths, and K. J. Hughes, “Significance of the HO₂+CO Reaction during the Combustion of CO+H₂ Mixtures at High Pressures,” Proceedings of the Combustion Institute 31, 419-427 (2007).
X. You, H. Wang, E. Goos, C. J. Sung, and S. J. Klippenstein, “Reaction Kinetics of CO+HO₂→Products: Ab Initio Study and Master Equation Modeling,” Journal of Physical Chemistry A, Journal of Physical Chemistry A 111, 4031-4042 (2007).
G. Mittal and C. J. Sung, “Autoignition of Toluene and Benzene at Elevated Pressures in a Rapid Compression Machine,” Combustion and Flame 150, 355-368 (2007)
G. Mittal and C. J. Sung, “Homogeneous Charge Compression Ignition of Binary Fuel Blends,” Combustion and Flame 155, 431-439 (2008).
G. Mittal, M. Chaos, C. J. Sung, and F. L. Dryer, “Dimethyl Ether Autoignition in a Rapid Compression Machine: Experiments and Chemical Kinetic Modeling,” Fuel Processing Technology 89 (12), 1244-1254 (2008).
K. Kumar, G. Mittal, and C. J. Sung, “Autoignition of n-Decane under Elevated Pressure and Low-to-Intermediate Temperature Conditions,” Combustion and Flame 156, 1278-1288 (2009).
G. Mittal and C. J. Sung, “Autoignition of Methylcyclohexane at Elevated Pressures,” Combustion and Flame 156 (9), 1852-1855 (2009).
K. Kumar and C. J. Sung, “An Experimental Study of the Autoignition Characteristics of Conventional Jet Fuel/Oxidizer Mixtures: Jet-A and JP-8,” Combustion and Flame 157 (4), 676-685 (2010).
K. Kumar and C. J. Sung, “A Comparative Experimental Study of the Autoignition Characteristics of Alternative and Conventional Jet Fuel/Oxidizer Mixtures,” Fuel 89 (10), 2853-2863 (2010).
K. Kumar and C. J. Sung, “Autoignition of Methanol: Experiments and Computations,” International Journal of Chemical Kinetics 43 (4), 175-184 (2011).
B. W. Weber, K. Kumar, Y. Zhang, and C. J. Sung, “Autoignition of n-Butanol at Elevated Pressure and Low to Intermediate Temperature,” Combustion and Flame 158 (5), 809-819 (2011).
A. K. Das, C. J. Sung, Y. Zhang, and G. Mittal, “Ignition Delay Study of Moist Hydrogen/Oxidizer Mixtures using a Rapid Compression Machine,” International Journal of Hydrogen Energy 37 (8), 6901-6911 (2012).
G. Kukkadapu, K. Kumar, C. J. Sung, M. Mehl, and W. J. Pitz, “Experimental and Surrogate Modeling Study of Gasoline Ignition in a Rapid Compression Machine”, Combustion and Flame 159 (10), 3066-3078 (2012).
G. Kukkadapu, K. Kumar, C. J. Sung, M. Mehl, and W. J. Pitz, “Autoignition of Gasoline and its Surrogates in a Rapid Compression Machine”, Proceedings of Combustion Institute 34 (1), 345-352 (2013).
B. W. Weber and C. J. Sung, “Comparative Autoignition Trends in the Butanol Isomers at Elevated Pressure”, Energy and Fuels 27 (3), 1688-1698 (2013).
B. W. Weber, W. J. Pitz, M. Mehl, E. Silke, A. C. Davis, and C. J. Sung, “Experiments and Modeling of the Autoignition of Methylcyclohexane at High Pressure”, Combustion and Flame 161 (8), 1972-1983 (2014).
G. Kukkadapu, K. Kumar, C. J. Sung, M. Mehl, and W. J. Pitz, “Autoignition of Gasoline Surrogates at Low Temperature Combustion Conditions,” Combustion and Flame 162 (5), 2272-2285 (2015).
B. W. Weber, C. J. Sung, and M. W. Renfro, “On the Uncertainty of Temperature Estimation in a Rapid Compression Machine”,Combustion and Flame 162 (6), 2518-2528 (2015).
G. Kukkadapu, B. W Weber, and C. J. Sung, “Autoignition Study of Tetralin in a Rapid Compression Machine at Elevated Pressures and Low-to-Intermediate Temperatures”, Fuel 159, 436-445 (2015).
G. Kukkadapu and C. J. Sung, “Autoignition Study of ULSD#2 and FD9A Diesel Blends”, Combustion and Flame 166, 45-54 (2016).
G. Kukkadapu and C. J. Sung, “Autoignition Study of 1-Methylnaphthalene in a Rapid Compression Machine”, Energy and Fuels 31 (1), 854-866 (2017).
B. W. Weber, J. A. Bunnell, K. Kumar, and C. J. Sung, “Experiments and Modeling of the Autoignition of Methyl Pentanoate at Low to Intermediate Temperatures and Elevated Pressures in a Rapid Compression Machine”, Fuel 212, 479-486 (2018).
K. Kumar, C. J. Sung, B. W. Weber, and J. A. Bunnell, “Autoignition of Methyl Propanoate and its Comparisons with Methyl Ethanoate and Methyl Butanoate”, Combustion and Flame 188, 116-128 (2018).
G. Kukkadapu and C. J. Sung, “Autoignition of Binary Blends of n-Dodecane/1-Methylnaphthalene and iso-Cetane/1-Methylnaphthalene”, Combustion and Flame 189, 367-377 (2018).
M. Wang, K. Zhang, G. Kukkadapu, S. W. Wagnon, M. Mehl, W. J. Pitz, and C. J. Sung, “Autoignition of trans-Decalin, a Diesel Surrogate Compound: Rapid Compression Machine Experiments and Chemical Kinetic Modeling”, Combustion and Flame 194, 152-163 (2018).
H. Wang, R. Fang, B. W. Weber, and C. J. Sung, “An Experimental and Modeling Study of Dimethyl Ether/Methanol Blends Autoignition at Low Temperature”, Combustion and Flame 198, 89-99 (2018).
R. Fang, G. Kukkadapu, M. Wang, S. W. Wagnon, K. Zhang, M. Mehl, C. K. Westbrook, W. J. Pitz, and C. J. Sung, “Fuel Molecular Structure Effect on Autoignition of Highly Branched iso-Alkanes at Low-to-Intermediate Temperatures: iso-Octane versus iso-Dodecane”, Combustion and Flame 214, 152-166 (2020).
M. Wang, G. Kukkadapu, K. Zhang, S. W. Wagnon, M. Mehl, W. J. Pitz, C. K. Westbrook, and C. J. Sung, “Autoignition of CRC Diesel Surrogates at Low Temperature Combustion Conditions: Rapid Compression Machine Experiments and Modeling”, Combustion and Flame 219, 178-197 (2020).
R. Fang, C. Saggese, S. W. Wagnon, A. B. Sahu, H. J. Curran, W. J. Pitz, C. J. Sung, “Effect of nitric oxide and exhaust gases on gasoline surrogate autoignition: iso-octane experiments and modeling,” Combustion and Flame 236, 111807 (February 2022).
R. Fang and C. J. Sung, “A Rapid Compression Machine Study of 2-Phenylethanol Autoignition at Low-To-Intermediate Temperatures. Energies, ” Energies 14, 7708 (November 2021).
M. Liu, R. Fang, C. J. Sung, K. Alijohani, A. Farooq, Y. Almarzooq, O. Mathieu, E. L. Petersen, P. Dagaut, J. Zhao, Z. Tao, L. Yang, C. W. Zhou, “A Comprehensive experimental and modeling study of n-propylcyclohexane oxidation,” Combustion and Flame 238, 111944 (April 2022).