Modeling of flame-generated turbulence based on direct numerical simulation databases S Nishiki, T Hasegawa, R Borghi, R Himeno Proceedings of the Combustion Institute 29 (2), 2017-2022, 2002 | 111 | 2002 |
Modelling of turbulent scalar flux in turbulent premixed flames based on DNS databases S Nishiki, T Hasegawa, R Borghi, R Himeno Combustion Theory and Modelling 10 (1), 39-55, 2006 | 86 | 2006 |
A direct numerical simulation study of vorticity transformation in weakly turbulent premixed flames AN Lipatnikov, S Nishiki, T Hasegawa Physics of Fluids 26 (10), 2014 | 75 | 2014 |
Unburned mixture fingers in premixed turbulent flames AN Lipatnikov, J Chomiak, VA Sabelnikov, S Nishiki, T Hasegawa Proceedings of the Combustion Institute 35 (2), 1401-1408, 2015 | 71 | 2015 |
Zone conditional assessment of flame-generated turbulence with DNS database of a turbulent premixed flame YH Im, KY Huh, S Nishiki, T Hasegawa Combustion and flame 137 (4), 478-488, 2004 | 63 | 2004 |
A balance equation for the mean rate of product creation in premixed turbulent flames VA Sabelnikov, AN Lipatnikov, N Chakraborty, S Nishiki, T Hasegawa Proceedings of the Combustion Institute 36 (2), 1893-1901, 2017 | 32 | 2017 |
DNS assessment of a simple model for evaluating velocity conditioned to unburned gas in premixed turbulent flames AN Lipatnikov, VA Sabelnikov, S Nishiki, T Hasegawa, N Chakraborty Flow, Turbulence and Combustion 94, 513-526, 2015 | 28 | 2015 |
Does flame-generated vorticity increase turbulent burning velocity? AN Lipatnikov, VA Sabelnikov, S Nishiki, T Hasegawa Physics of Fluids 30 (8), 2018 | 27 | 2018 |
A direct numerical simulation study of the influence of flame-generated vorticity on reaction-zone-surface area in weakly turbulent premixed combustion AN Lipatnikov, VA Sabelnikov, S Nishiki, T Hasegawa Physics of Fluids 31 (5), 2019 | 25 | 2019 |
A DNS study of the physical mechanisms associated with density ratio influence on turbulent burning velocity in premixed flames AN Lipatnikov, J Chomiak, VA Sabelnikov, S Nishiki, T Hasegawa Combustion Theory and Modelling 22 (1), 131-155, 2018 | 25 | 2018 |
A transport equation for reaction rate in turbulent flows VA Sabelnikov, AN Lipatnikov, N Chakraborty, S Nishiki, T Hasegawa Physics of Fluids 28 (8), 2016 | 25 | 2016 |
DNS assessment of relation between mean reaction and scalar dissipation rates in the flamelet regime of premixed turbulent combustion AN Lipatnikov, S Nishiki, T Hasegawa Combustion Theory and Modelling 19 (3), 309-328, 2015 | 23 | 2015 |
Combustion-induced local shear layers within premixed flamelets in weakly turbulent flows AN Lipatnikov, VA Sabelnikov, S Nishiki, T Hasegawa Physics of Fluids 30 (8), 2018 | 22 | 2018 |
Simulation of tunnel fire for evacuation safety assessment K Yamamoto, Y Sawaguchi, S Nishiki Safety 4 (2), 12, 2018 | 21 | 2018 |
DNS and modeling of turbulent premixed combustion S Nishiki These de Doctorat, Nagoya Institue of Technology (Japan), 2003 | 21 | 2003 |
Investigation of the influence of combustion-induced thermal expansion on two-point turbulence statistics using conditioned structure functions VA Sabelnikov, AN Lipatnikov, S Nishiki, T Hasegawa Journal of Fluid Mechanics 867, 45-76, 2019 | 20 | 2019 |
Mechanism of flame evolution along a fine vortex T Hasegawa, R Nakamichi, S Nishiki Combustion Theory and Modelling 6 (3), 413, 2002 | 20 | 2002 |
Dissipation and dilatation rates in premixed turbulent flames VA Sabelnikov, AN Lipatnikov, S Nishiki, HL Dave, FE Hernández Pérez, ... Physics of Fluids 33 (3), 2021 | 19 | 2021 |
Flamelet perturbations and flame surface density transport in weakly turbulent premixed combustion AN Lipatnikov, VA Sabelnikov, S Nishiki, T Hasegawa Combustion Theory and Modelling 21 (2), 205-227, 2017 | 19 | 2017 |
Application of conditioned structure functions to exploring influence of premixed combustion on two-point turbulence statistics VA Sabelnikov, AN Lipatnikov, S Nishiki, T Hasegawa Proceedings of the Combustion Institute 37 (2), 2433-2441, 2019 | 18 | 2019 |