A detailed kinetic modeling study of aromatics formation in laminar premixed acetylene and ethylene flames H Wang, M Frenklach Combustion and flame 110 (1-2), 173-221, 1997 | 1701 | 1997 |
USC Mech Version II. High-Temperature Combustion Reaction Model of H2/CO/C1-C4 Compounds H Wang, X You, AV Joshi, SG Davis, A Laskin, F Egolfopoulos, CK Law http://ignis.usc.edu/USC_Mech_II.htm, 2007 | 1695* | 2007 |
Detailed mechanism and modeling of soot particle formation M Frenklach, H Wang Soot formation in combustion, 165-192, 1994 | 1613* | 1994 |
Detailed modeling of soot particle nucleation and growth M Frenklach, H Wang Symposium (International) on Combustion 23 (1), 1559-1566, 1991 | 1529 | 1991 |
Formation of nascent soot and other condensed-phase materials in flames H Wang Proceedings of the Combustion Institute 33 (1), 41-67, 2011 | 1299 | 2011 |
An optimized kinetic model of H2/CO combustion SG Davis, AV Joshi, H Wang, F Egolfopoulos Proceedings of the Combustion Institute 30 (1), 1283-1292, 2005 | 914 | 2005 |
Gri-mech 1.2-an optimized detailed chemical reaction mechanism for methane combustion M Frenklach, H Wang, C Yu, M Goldenberg, C Bowman, R Hanson, ... GRI Tech. Report GRI-95/0058, 1995 | 726* | 1995 |
Detailed surface and gas-phase chemical kinetics of diamond deposition M Frenklach, H Wang Physical Review B 43 (2), 1520, 1991 | 603 | 1991 |
Optimization and analysis of large chemical kinetic mechanisms using the solution mapping method—combustion of methane M Frenklach, H Wang, MJ Rabinowitz Progress in Energy and Combustion Science 18 (1), 47-73, 1992 | 563 | 1992 |
A high-temperature chemical kinetic model of n-alkane (up to n-dodecane), cyclohexane, and methyl-, ethyl-, n-propyl and n-butyl-cyclohexane oxidation at high temperatures H Wang, E Dames, B Sirjean, DA Sheen, R Tangko, A Violi, JYW Lai, ... JetSurF version 2, 19, 2010 | 505* | 2010 |
Propagation and extinction of premixed C5–C12 n-alkane flames C Ji, E Dames, YL Wang, H Wang, FN Egolfopoulos Combustion and Flame 157 (2), 277-287, 2010 | 456 | 2010 |
Calculations of rate coefficients for the chemically activated reactions of acetylene with vinylic and aromatic radicals H Wang, M Frenklach The Journal of Physical Chemistry 98 (44), 11465-11489, 1994 | 432 | 1994 |
Combustion chemistry of propane: a case study of detailed reaction mechanism optimization Z Qin, VV Lissianski, H Yang, WC Gardiner, SG Davis, H Wang Proceedings of the Combustion Institute 28 (2), 1663-1669, 2000 | 421 | 2000 |
A physics-based approach to modeling real-fuel combustion chemistry-I. Evidence from experiments, and thermodynamic, chemical kinetic and statistical considerations H Wang, R Xu, K Wang, CT Bowman, RK Hanson, DF Davidson, ... Combustion and Flame 193, 502-519, 2018 | 409 | 2018 |
Detailed modeling of soot formation in laminar premixed ethylene flames at a pressure of 10 bar A Kazakov, H Wang, M Frenklach Combustion and Flame 100 (1-2), 111-120, 1995 | 386 | 1995 |
A physics-based approach to modeling real-fuel combustion chemistry–II. Reaction kinetic models of jet and rocket fuels R Xu, K Wang, S Banerjee, J Shao, T Parise, Y Zhu, S Wang, A Movaghar, ... Combustion and Flame 193, 520-537, 2018 | 344 | 2018 |
Measurement and numerical simulation of soot particle size distribution functions in a laminar premixed ethylene-oxygen-argon flame B Zhao, Z Yang, MV Johnston, H Wang, AS Wexler, M Balthasar, M Kraft Combustion and Flame 133 (1-2), 173-188, 2003 | 344 | 2003 |
Combustion kinetic model uncertainty quantification, propagation and minimization H Wang, DA Sheen Progress in Energy and Combustion Science 47, 1-31, 2015 | 336 | 2015 |
Transport properties of polycyclic aromatic hydrocarbons for flame modeling H Wang, M Frenklach Combustion and flame 96 (1-2), 163-170, 1994 | 328 | 1994 |
Propene pyrolysis and oxidation kinetics in a flow reactor and laminar flames SG Davis, CK Law, H Wang Combustion and Flame 119 (4), 375-399, 1999 | 310 | 1999 |