11 |
Study on status characteristics and oxidation reactivity of biodiesel particulate matter Li RN, Wang Z Fuel, 218, 218, 2018 |
12 |
Effect of acetone-butanol-ethanol addition to diesel on the soot reactivity Luo JF, Zhang YM, Wang JJ, Zhang QX Fuel, 226, 555, 2018 |
13 |
Theoretical kinetic studies for low temperature oxidation of two typical methylcyclohexyl radicals Xing LL, Zhang LD, Zhang F, Jiang J Combustion and Flame, 182, 216, 2017 |
14 |
Air and water oxidation of aluminum flake particles Antipina SA, Zmanovskii SV, Gromov AA, Teipel U Powder Technology, 307, 184, 2017 |
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Reactivity and structure of soot generated at varying biofuel content and engine operating parameters Ess MN, Bladt H, Muhlbauer W, Seher SI, Zollner C, Lorenz S, Bruggemann D, Nieken U, Ivleva NP, Niessner R Combustion and Flame, 163, 157, 2016 |
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Correlations between physicochemical properties of emitted diesel particulate matter and its reactivity Muhlbauer W, Zollner C, Lehmann S, Lorenz S, Bruggemann D Combustion and Flame, 167, 39, 2016 |
17 |
Lube oil-dependent ash chemistry on soot oxidation reactivity in a gasoline direct-injection engine Choi S, Seong H Combustion and Flame, 174, 68, 2016 |
18 |
Influence of waste cooking oil biodiesel on oxidation reactivity and nanostructure of particulate matter from diesel engine Qu L, Wang Z, Zhang J Fuel, 181, 389, 2016 |
19 |
Impact of intake hydrogen enrichment on morphology, structure and oxidation reactivity of diesel particulate Zhou JH, Cheung CS, Zhao WZ, Ning Z, Leung CW Applied Energy, 160, 442, 2015 |
20 |
Oxidation characteristics of gasoline direct-injection (GDI) engine soot: Catalytic effects of ash and modified kinetic correlation Choi S, Seong H Combustion and Flame, 162(6), 2371, 2015 |