1 N. Peters, "The computation of stretched laminar methane-air diffusion flames using a reduced four-step mechanism" 68 : 17-29, 1987
2 T.F. Lu, "Strategies for mechanism reduction for large hydrocarbons: n-heptane" 154 : 153-163, 2008
3 K. E. Niemeyer, "Skeletal mechanism generation for surrogate fuels" Case western Reserve University 2010
4 U. Maas, "Simplifying chemical kinetics:Intrinsic low-dimensional manifolds in composition space" 88 : 239-264, 1992
5 T. Turanyi, "Reduction of large reaction mechanisms" 14 : 795-803, 1990
6 M.D. Smooke, "Reduced kinetic mechanisms and asymptotic approximations for methan-air flames" Springer-Verlag 384 : 1-28, 1991
7 W. J. Pitz, "Recent Progress in the development of diesel surrogate fuels" 37 : 330-350, 2011
8 N. Peters, "Numerical Simulation of Combustion Phenomena" Springer 241 : 90-109, 1985
9 A.S. Tomlin, "Mecahanism reduction for the oscillatory oxidation of hydrogen: Sensitivity and quasi-steady-sate analyses" 91 : 107-130, 1992
10 T.F. Lu, "Linear time reduction of large kinetic mechanism with directed realtion graph: n-Heptane and iso-octane" 144 : 24-36, 2006
1 N. Peters, "The computation of stretched laminar methane-air diffusion flames using a reduced four-step mechanism" 68 : 17-29, 1987
2 T.F. Lu, "Strategies for mechanism reduction for large hydrocarbons: n-heptane" 154 : 153-163, 2008
3 K. E. Niemeyer, "Skeletal mechanism generation for surrogate fuels" Case western Reserve University 2010
4 U. Maas, "Simplifying chemical kinetics:Intrinsic low-dimensional manifolds in composition space" 88 : 239-264, 1992
5 T. Turanyi, "Reduction of large reaction mechanisms" 14 : 795-803, 1990
6 M.D. Smooke, "Reduced kinetic mechanisms and asymptotic approximations for methan-air flames" Springer-Verlag 384 : 1-28, 1991
7 W. J. Pitz, "Recent Progress in the development of diesel surrogate fuels" 37 : 330-350, 2011
8 N. Peters, "Numerical Simulation of Combustion Phenomena" Springer 241 : 90-109, 1985
9 A.S. Tomlin, "Mecahanism reduction for the oscillatory oxidation of hydrogen: Sensitivity and quasi-steady-sate analyses" 91 : 107-130, 1992
10 T.F. Lu, "Linear time reduction of large kinetic mechanism with directed realtion graph: n-Heptane and iso-octane" 144 : 24-36, 2006
11 A. Massias, "Global reduced mechanisms for methane and hydrogen combustion with nitric oxide formation constructed with CSP data" 3 : 233-257, 1999
12 J. L. Brakora, "Development and validation of a reduced reaction mechanism for biodiesel-fueled engine simulation" SAE 2008
13 H. Wang, "Detailed reduction of reaction mechanisms for flame modeling" 87 : 365-370, 1991
14 E. M. Fisher, "Detailed chemical kinetic mechanisms for combustion of oxygenated fuels" 28 : 1579-1586, 2000
15 T.F. Lu, "Complex CSP for chemistry reduction and analysis" 126 : 1445-1455, 2001
16 B. AKih-Kumgeh, "Comparative study of methyl butanoate and n-heptane high temperature autoignition" 24 (24): 2439-2448, 2010
17 R. J. Kee, "Chemkin-II: A FORTRAN chemical Kinetics Package for the Analysis of Gas-Phase Chemical Kinetics" 1989
18 A. Massias, "An algorithm for the construction of global reduced mechanisms with CSP data" 117 : 685-708, 1999
19 J.Y. Chen, "A general procedure for constructing reduced reaction mechanisms with given independent relations" 57 : 89-94, 1988
20 T.F. Lu, "A directed relation graph method for mechanism reduction" 30 : 1333-1341, 2005