1 |
Hydrogen effects on ignition delay time of methyl butanoate in a rapid compression machine Lee S, Song S International Journal of Energy Research, 45(4), 5602, 2021 |
2 |
Autoignition of methyl propanoate and its comparisons with methyl ethanoate and methyl butanoate Kumar K, Sung CJ, Weber BW, Bunnell JA Combustion and Flame, 188, 116, 2018 |
3 |
Experimental and modeling studies of small typical methyl esters pyrolysis: Methyl butanoate and methyl crotonate Zhai YT, Feng BB, Yuan WH, Ao CC, Zhang LD Combustion and Flame, 191, 160, 2018 |
4 |
Experimental and chemical kinetic modeling investigation of methyl butanoate as a component of biodiesel surrogate Lele AD, Vallabhuni SK, Moshammer K, Fernandes RX, Krishnasamy A, Narayanaswamy K Combustion and Flame, 197, 49, 2018 |
5 |
High capacity Li-ion battery anodes: Impact of crystallite size, surface chemistry and PEG-coating Minnici K, Kwon YH, Huie MM, de Simon MV, Zhang BJ, Bock DC, Wang JJ, Wang J, Takeuchi KJ, Takeuchi ES, Marschilok AC, Reichmanis E Electrochimica Acta, 260, 235, 2018 |
6 |
A fundamental investigation into chemical effects of carbon dioxide on intermediate temperature oxidation of biodiesel surrogate with laminar flow reactor Li A, Zhu L, Deng ZW, Gao Z, Huang Z Energy, 141, 20, 2017 |
7 |
Impact of methyl butanoate oxidation on NO formation in laminar low pressure flames Sylla MD, Lamoureux N, Gasnot L Fuel, 207, 801, 2017 |
8 |
Autoignition of methyl butanoate under engine relevant conditions Kumar K, Sung CJ Combustion and Flame, 171, 1, 2016 |
9 |
Formation of unsaturated hydrocarbons, carbonyl compounds and PAHs in a non-premixed methane/air flame doped with methyl butanoate: CFD modeling and comparison with experimental data Lin KC, Chiu CT, Tao HR, Liao YC Fuel, 182, 487, 2016 |
10 |
Rapid compression machine studies on ignition delay changes in a methyl butanoate/n-heptane mixture by hydrogen addition Lee S, Song S International Journal of Hydrogen Energy, 41(42), 19207, 2016 |