1 이기용, "대용 디젤연료의 대향류 비예혼합 화염에서 Methyl Decanoate 첨가가 방향족 생성에 미치는 영향" 한국연소학회 24 (24): 11-17, 2019
2 W. Sun, "Speciation and the laminar burning velocities of poly(oxymethylene)dimethyl ether 3(POMDME3)flames : an experimental and modeling study" 36 : 1269-1278, 2017
3 C. W. Gao, "Reaction Mechanism Generator: Automatic construction of chemical kinetic mechanisms" 203 : 212-225, 2016
4 L. Golka, "Pyrolysis of dimethoxymethane and the reaction of dimethoxymethane with H atoms: a shock-tube/ARAS/TOF-MS and modeling study" 37 : 179-187, 2019
5 V. Dieterich, "Power-to-liquid via synthesis of methanol, DME or Fischer–Tropsch-fuels: a review" 13 (13): 3207-3252, 2020
6 D. Pélerin, "Potentials to simplify the engine system using the alternative diesel fuels oxymethylene ether OME1 and OME3−6 on a heavy-duty engine" 259 : 116231-, 2020
7 A. Omari, "Potential of long-chain oxymethylene ether and oxymethylene ether-diesel blends for ultra-low emission engines" 239 : 1242-1249, 2019
8 J. Wullenkord, "Laminar premiexed and non-premixed flame investigation on the influence of dimethyl ether addition on n-heptane combustion" 212 : 323-336, 2020
9 K. Seshadri, "Laminar flow between parallel plates with injection of a reactant at high reynolds number" 21 (21): 251-253, 1978
10 "IEA World Energy Outlook 2020" International Energy Agency 2020
1 이기용, "대용 디젤연료의 대향류 비예혼합 화염에서 Methyl Decanoate 첨가가 방향족 생성에 미치는 영향" 한국연소학회 24 (24): 11-17, 2019
2 W. Sun, "Speciation and the laminar burning velocities of poly(oxymethylene)dimethyl ether 3(POMDME3)flames : an experimental and modeling study" 36 : 1269-1278, 2017
3 C. W. Gao, "Reaction Mechanism Generator: Automatic construction of chemical kinetic mechanisms" 203 : 212-225, 2016
4 L. Golka, "Pyrolysis of dimethoxymethane and the reaction of dimethoxymethane with H atoms: a shock-tube/ARAS/TOF-MS and modeling study" 37 : 179-187, 2019
5 V. Dieterich, "Power-to-liquid via synthesis of methanol, DME or Fischer–Tropsch-fuels: a review" 13 (13): 3207-3252, 2020
6 D. Pélerin, "Potentials to simplify the engine system using the alternative diesel fuels oxymethylene ether OME1 and OME3−6 on a heavy-duty engine" 259 : 116231-, 2020
7 A. Omari, "Potential of long-chain oxymethylene ether and oxymethylene ether-diesel blends for ultra-low emission engines" 239 : 1242-1249, 2019
8 J. Wullenkord, "Laminar premiexed and non-premixed flame investigation on the influence of dimethyl ether addition on n-heptane combustion" 212 : 323-336, 2020
9 K. Seshadri, "Laminar flow between parallel plates with injection of a reactant at high reynolds number" 21 (21): 251-253, 1978
10 "IEA World Energy Outlook 2020" International Energy Agency 2020
11 L. Marrodán, "High pressure oxidation of dimethoxymethane" 29 : 3507-3517, 2015
12 B. Chen, "Exploring the combustion chemistry of anisole in laminar counterflow diffusionflames under oxy-fuel conditions" 243 : 111929-, 2022
13 S. A. Issacs, "Environmental and Economic Performance of Hybrid Power-to-Liquid and Biomass-to-Liquid Fuel Production in the United States" 55 (55): 8247-8257, 2021
14 S. W. Wagnon, "Effects of buffer gas composition on autoignition" 161 (161): 898-907, 2014
15 S. Jacobs, "Detailed kinetic modeling of dimethoxymethane. Part II: experimental and theoretical study of the kinetics and reaction mechanism" 205 : 522-533, 2019
16 J. A. Cooke, "Computational and experimental study of JP-8, a surrogate, and its component in counterflow diffusion flames" 30 : 439-446, 2005
17 J. Yanowitz, "Compendium of Experimental Cetane Numbers" National Renewable Energy Laboratory 2017
18 D. G. Goodwin, "Cantera: An object-oriented software toolkit for chemical kinetics, thermodynamics, and transport processes, Version 2.6.0"
19 S. M. Sarathy, "An experimental and kinetic modeling study of methyl decanoate combustion" 33 (33): 399-405, 2011
20 K. De Ras, "A detailed experimental and kinetic modeling study on pyrolysis and oxidation of oxymethylene ether-2 (OME-2)" 238 : 111914-, 2022
21 L. Xu, "A comparative study of the sooting tendencies of various C5-C8 alkanes, alkenes and cycloalkanes in counterflow diffusion flames" 1-4 : 100007-, 2020
22 T. He, "A chemical kinetic mechanism for the low- and intermediate-temperature combustion of Polyoxymethylene Dimethyl Ether 3 (PODE3)" 212 : 223-235, 2018
23 Y. Pei, "A Multicomponent Blend as a Diesel Fuel Surrogate for Compression Ignition Engine Applications" 137 (137): 111502-, 2015