| Soot formation in high pressure laminar diffusion flames AE Karataş, ÖL Gülder Progress in Energy and Combustion Science 38 (6), 818-845, 2012 | 348 | 2012 |
| Numerical and experimental study of the influence of CO2 and N2 dilution on soot formation in laminar coflow C2H4/air diffusion flames at pressures between 5 and 20 atm F Liu, AE Karataş, ÖL Gülder, M Gu Combustion and Flame 162 (5), 2231-2247, 2015 | 122 | 2015 |
| Sooting behaviour of n-heptane laminar diffusion flames at high pressures AE Karataş, G Intasopa, ÖL Gülder Combustion and Flame 160 (9), 1650-1656, 2013 | 75 | 2013 |
| On the effect of pressure on soot nanostructure: A Raman spectroscopy investigation M Commodo, AE Karataş, G De Falco, P Minutolo, A D’Anna, ÖL Gülder Combustion and Flame 219, 13-19, 2020 | 56 | 2020 |
| Dependence of sooting characteristics and temperature field of co-flow laminar pure and nitrogen-diluted ethylene–air diffusion flames on pressure AE Karataş, ÖL Gülder Combustion and Flame 162 (4), 1566-1574, 2015 | 55 | 2015 |
| Soot aggregate morphology in coflow laminar ethylene diffusion flames at elevated pressures B Gigone, AE Karataş, ÖL Gülder Proceedings of the Combustion Institute 37 (1), 841-848, 2019 | 43 | 2019 |
| Effects of carbon dioxide and nitrogen addition on soot processes in laminar diffusion flames of ethylene-air at high pressures AE Karataş, ÖL Gülder Fuel 200, 76-80, 2017 | 41 | 2017 |
| Soot formation in co-and counter-flow laminar diffusion flames of binary mixtures of ethylene and butane isomers and synergistic effects AE Karataş, M Commodo, OL Gülder Energy & fuels 24 (9), 4912-4918, 2010 | 31 | 2010 |
| Soot aggregate morphology deduced from thermophoretic sampling in coflow laminar methane diffusion flames at pressures up to 30 bar AE Karataş, B Gigone, ÖL Gülder Combustion and Flame 222, 411-422, 2020 | 26 | 2020 |
| Effect of hydrogen enrichment of laminar ethylene diffusion flames on thermal structure and soot yields at pressures up to 10 bar SS Yang, AE Karataş, ÖL Gülder Proceedings of the Combustion Institute 38 (2), 2507-2516, 2021 | 25 | 2021 |
| Investigation of soot suppression by ammonia addition to laminar ethylene flames at varying pressure F Cepeda, SB Dworkin, AE Karataş Combustion and Flame 251, 112728, 2023 | 24 | 2023 |
| Effects of oxygen on soot formation in laminar co-flow flames of binary mixtures of ethane, DME, and oxygen M Serwin, AE Karataş Combustion and Flame 229, 111413, 2021 | 24 | 2021 |
| Understanding lifetime and dispersion of cough-emitted droplets in air K Lordly, L Kober, M Jadidi, S Antoun, SB Dworkin, AE Karataş Indoor and Built Environment 32 (10), 1929-1948, 2023 | 19 | 2023 |
| A calibration-free two-dimensional spectral soot emission platform for temperature and soot measurements M Serwin, AE Karataş Experimental Thermal and Fluid Science 130, 110493, 2022 | 17 | 2022 |
| Combined experimental and numerical study of ethanol laminar flame extinction W Wang, AE Karataş, CPT Groth, ÖL Gülder Combustion Science and Technology 190 (8), 1472-1487, 2018 | 14 | 2018 |
| Experimental and numerical study of laminar flame extinction for syngas and syngas-methane blends W Wang, AE Karatas, CPT Groth, ÖL Gülder Combustion Science and Technology 190 (8), 1455-1471, 2018 | 14 | 2018 |
| Soot Fformation in Co-flow and Counterflow Laminar Diffusion Flames of Fuel Mixtures AE Karatas | 12 | 2010 |
| High-pressure soot formation and diffusion flame extinction characteristics of gaseous and liquid fuels AE Karatas University of Toronto (Canada), 2014 | 11 | 2014 |
| Feasibility study of electrified light-sport aircraft powertrains M McQueen, AE Karataş, G Bramesfeld, E Demir, O Arenas Aerospace 9 (4), 224, 2022 | 9 | 2022 |
| On the sudden reversal of soot formation by oxygen addition in DME flames F Cepeda, L Di Liddo, M Serwin, AE Karataş, SB Dworkin Proceedings of the Combustion Institute 39 (2), 1997-2005, 2023 | 8 | 2023 |
