| 1 |
High-pressure shock-tube study of the ignition and product formation of fuel-rich dimethoxymethane (DMM)/air and CH4/DMM/air mixtures
Herzler J, Fikri M, Schulz C
Combustion and Flame, 216, 293, 2020 |
| 2 |
Revisiting the chemical kinetics of CH3 + O-2 and its impact on methane ignition
Zhang F, Huang C, Xie BB, Wu XQ
Combustion and Flame, 200, 125, 2019 |
| 3 |
Study on the combustion characteristics and ignition limits of the methane homogeneous charge compression ignition with hydrogen addition in micro-power devices
Wang Q, Zhao Y, Wu F, Bai J
Fuel, 236, 354, 2019 |
| 4 |
Effect of injection timing on the ignition process of n-heptane spray flame in a methane/air environment
Wei HQ, Zhao WH, Qi JY, Liu ZK, Zhou L
Fuel, 245, 345, 2019 |
| 5 |
Computation of methane/air ignition delay and excitation times, using comprehensive and reduced chemical mechanisms and their relevance in engine autoignition
Bates L, Bradley D, Gorbatenko I, Tomlin AS
Combustion and Flame, 185, 105, 2017 |
| 6 |
An RCM experimental and modeling study on CH4 and CH4/C2H6 oxidation at pressures up to 160 bar
Ramalingam A, Zhang KW, Dhongde A, Virnich L, Sankhla H, Curran H, Heufer A
Fuel, 206, 325, 2017 |
| 7 |
High-pressure oxidation of methane
Hashemi H, Christensen JM, Gersen S, Levinsky H, Klippenstein SJ, Glarborg P
Combustion and Flame, 172, 349, 2016 |
| 8 |
Influence of coal particles on methane/air mixture ignition in a heated environment
Li G, Li C, Huang DZ, Yuan CM
Journal of Loss Prevention in The Process Industries, 26(1), 91, 2013 |
| 9 |
Methane-air mixtures ignited by CW laser-heated targets on optical fiber tips: Comparison of targets, optical fibers, and ignition delays
Dubamewicz TH
Journal of Loss Prevention in The Process Industries, 19(5), 425, 2006 |
| 10 |
Shock-tube study of methane ignition under engine-relevant conditions: experiments and modeling
Huang J, Hill PG, Bushe WK, Munshi SR
Combustion and Flame, 136(1-2), 25, 2004 |
