| 1 |
Development of a skeletal mechanism for four-component biodiesel surrogate fuel with PAH
Bai YQ, Wang Y, Wang XC
Renewable Energy, 171, 266, 2021 |
| 2 |
Development of a skeletal surrogate mechanism for emulating combustion characteristics of diesel from direct coal liquefaction
Fang XY, Huang XY, Chen WK, Qiao XQ, Ju DH
Combustion and Flame, 218, 84, 2020 |
| 3 |
Skeletal mechanism construction for heavy saturated methyl esters in real biodiesel fuels
Li H, Yang WM, Zhou DZ, Yu WB
Fuel, 239, 263, 2019 |
| 4 |
Measurement of laminar burning velocity of n-pentanol plus air mixtures at elevated temperatures and a skeletal kinetic model
Katoch A, Alfazazi A, Sarathy SM, Chauhan A, Kumar R, Kumar S
Fuel, 237, 10, 2019 |
| 5 |
On the application of tabulated dynamic adaptive chemistry in ethylene-fueled supersonic combustion
Wu K, Contino F, Yao W, Fan XJ
Combustion and Flame, 197, 265, 2018 |
| 6 |
Development of an optimization methodology for formulating both jet fuel and diesel fuel surrogates and their associated skeletal oxidation mechanisms
Yu WB, Zhao FY, Yang WM, Tay KL, Xu HP
Fuel, 231, 361, 2018 |
| 7 |
Automatic generation of a kinetic skeletal mechanism for methane-hydrogen blends with nitrogen chemistry
Wang T, Zhang X, Zhang JB, Hou XS
International Journal of Hydrogen Energy, 43(6), 3330, 2018 |
| 8 |
A compact skeletal mechanism for n-dodecane with optimized semi-global low-temperature chemistry for diesel engine simulations
Yao T, Pei YJ, Zhong BJ, Som S, Lu TF, Luo KH
Fuel, 191, 339, 2017 |
| 9 |
A compact skeletal mechanism of propane towards applications from NTC-affected ignition predictions to CFD-modeled diffusion flames: Comparisons with experiments
Lin KC, Chiu CT
Fuel, 203, 102, 2017 |
| 10 |
Ab initio calculation and kinetic modeling study of diethyl ether ignition with application toward a skeletal mechanism for CI engine modeling
Hu EJ, Chen YL, Zhang ZH, Chen JY, Huang ZH
Fuel, 209, 509, 2017 |
