11 |
Development of a skeletal mechanism for diesel surrogate fuel by using a decoupling methodology Chang YC, Jia M, Li YP, Liu YD, Xie MZ, Wang H, Reitz RD Combustion and Flame, 162(10), 3785, 2015 |
12 |
Development of a skeletal multi-component fuel reaction mechanism based on decoupling methodology Mohan B, Tay KL, Yang WM, Chua KJ Energy Conversion and Management, 105, 1223, 2015 |
13 |
A Soot Precursor Formation Embedded Reaction Mechanism of Diesel Surrogate Fuel Wang F, Zheng ZL, He ZW Energy Sources Part A-recovery Utilization and Environmental Effects, 37(12), 1323, 2015 |
14 |
Fuel and diluent property effects during wet compression of a fuel aerosol under RCM conditions Goldsborough SS, Johnson MV, Zhu GS, Aggarwal SK Fuel, 93(1), 454, 2012 |
15 |
A method to determine ignition delay times for Diesel surrogate fuels from combustion in a constant volume bomb: Inverse Livengood-Wu method Reyes M, Tinaut FV, Andres C, Perez A Fuel, 102, 289, 2012 |
16 |
Recent progress in the development of diesel surrogate fuels Pitz WJ, Mueller CJ Progress in Energy and Combustion Science, 37(3), 330, 2011 |
17 |
A detailed experimental study of n-propylcyclohexane autoignition in lean conditions Crochet M, Minetti R, Ribaucour M, Vanhove G Combustion and Flame, 157(11), 2078, 2010 |
18 |
Experimental study of soot formation from a diesel fuel surrogate in a shock tube Mathieu O, Djebaili-Chaumeix N, Paillard CE, Douce F Combustion and Flame, 156(8), 1576, 2009 |
19 |
A soot formation embedded reduced reaction mechanism for diesel surrogate fuel Chen WM, Shuai SJ, Wang JX Fuel, 88(10), 1927, 2009 |
20 |
Hydrogen production for fuel cell by oxidative reforming of diesel surrogate: Influence of ceria and/or lanthana over the activity of Pt/Al2O3 catalysts Alvarez-Galvan MC, Navarro RM, Rosa F, Briceno Y, Ridao MA, Fierro JLG Fuel, 87(12), 2502, 2008 |