Related references
Note: Only part of the references are listed.Construction and derivation of a series of skeletal chemical mechanisms for n-alkanes with uniform and decoupling structure based on reaction rate rules
Yachao Chang et al.
COMBUSTION AND FLAME (2022)
A detailed chemical kinetic modeling and experimental investigation of the low- and high-temperature chemistry of n-butylcyclohexane
William J. Pitz et al.
INTERNATIONAL JOURNAL OF CHEMICAL KINETICS (2021)
A comprehensive combustion chemistry study of n- propylcyclohexane
Ahfaz Ahmed et al.
COMBUSTION AND FLAME (2021)
Reduction of large-scale chemical mechanisms using global sensitivity analysis on reaction class/sub-mechanism
Yachao Chang et al.
COMBUSTION AND FLAME (2020)
Experimental and kinetic modeling investigation on ethylcyclohexane low-temperature oxidation in a jet-stirred reactor
Jiabiao Zou et al.
COMBUSTION AND FLAME (2020)
Methylcyclohexane pyrolysis and oxidation in a jet-stirred reactor
Tony Bissoonauth et al.
PROCEEDINGS OF THE COMBUSTION INSTITUTE (2019)
An experimental and kinetic modeling study of n-butylcyclohexane over low-to-high temperature ranges
Yebing Mao et al.
COMBUSTION AND FLAME (2019)
Reduction of a detailed chemical mechanism for a kerosene surrogate via RCCE-CSP
Panos Koniavitis et al.
COMBUSTION AND FLAME (2018)
Reaction Mechanism Generator: Automatic construction of chemical kinetic mechanisms
Connie W. Gao et al.
COMPUTER PHYSICS COMMUNICATIONS (2016)
Comparison study of the gas-phase oxidation of alkylbenzenes and alkylcyclohexanes
Olivier Herbinet et al.
CHEMICAL ENGINEERING SCIENCE (2015)
Kinetics of ethylcyclohexane pyrolysis and oxidation: An experimental and detailed kinetic modeling study
Zhandong Wang et al.
COMBUSTION AND FLAME (2015)
Experimental and kinetic modeling study on methylcyclohexane pyrolysis and combustion
Zhandong Wang et al.
COMBUSTION AND FLAME (2014)
Experiments and modeling of the autoignition of methylcyclohexane at high pressure
Bryan W. Weber et al.
COMBUSTION AND FLAME (2014)
An experimental and reduced modeling study of the laminar flame speed of jet fuel surrogate components
J. D. Munzar et al.
FUEL (2013)
Laminar flame speeds of cyclohexane and mono-alkylated cyclohexanes at elevated pressures
Fujia Wu et al.
COMBUSTION AND FLAME (2012)
Detailed Product Analysis during Low- and Intermediate-Temperature Oxidation of Ethylcyclohexane
B. Husson et al.
JOURNAL OF PHYSICAL CHEMISTRY A (2012)
Low temperature oxidation of n-butylcyclohexane
Robert H. Natelson et al.
COMBUSTION AND FLAME (2011)
A comparative study of the oxidation characteristics of cyclohexane, methylcyclohexane, and n-butylcyclohexane at high temperatures
Zekai Hong et al.
COMBUSTION AND FLAME (2011)
An experimental and modeling study of the propagation of cyclohexane and mono-alkylated cyclohexane flames
Chunsheng Ji et al.
PROCEEDINGS OF THE COMBUSTION INSTITUTE (2011)
Recent progress in the development of diesel surrogate fuels
William J. Pitz et al.
PROGRESS IN ENERGY AND COMBUSTION SCIENCE (2011)
Experimental and Modeling Study of n-Propylcyclohexane Oxidation under Engine-relevant Conditions
Thomas Dubois et al.
ENERGY & FUELS (2009)
Shock Tube Study of Methylcyclohexane Ignition over a Wide Range of Pressure and Temperature
Subith S. Vasu et al.
ENERGY & FUELS (2009)
Ignition Time Measurements for Methylcylcohexane- and Ethylcyclohexane-Air Mixtures at Elevated Pressures
Jeremy Vanderover et al.
INTERNATIONAL JOURNAL OF CHEMICAL KINETICS (2009)
Modeling and experimental investigation of methylcyclohexane ignition in a rapid compression machine
W. J. Pitz et al.
PROCEEDINGS OF THE COMBUSTION INSTITUTE (2007)
Experimental and modeling study of methyl cyclohexane pyrolysis and oxidation
JP Orme et al.
JOURNAL OF PHYSICAL CHEMISTRY A (2006)
Share Paper
