| A consistent LES/filtered-density function formulation for the simulation of turbulent flames with detailed chemistry V Raman, H Pitsch Proceedings of the Combustion Institute 31 (2), 1711-1719, 2007 | 270 | 2007 |
| Hybrid large-eddy simulation/Lagrangian filtered-density-function approach for simulating turbulent combustion V Raman, H Pitsch, RO Fox Combustion and Flame 143 (1-2), 56-78, 2005 | 234 | 2005 |
| Large-eddy simulation of a bluff-body-stabilized non-premixed flame using a recursive filter-refinement procedure V Raman, H Pitsch Combustion and flame 142 (4), 329-347, 2005 | 165 | 2005 |
| Optimized reaction mechanism rate rules for ignition of normal alkanes L Cai, H Pitsch, SY Mohamed, V Raman, J Bugler, H Curran, SM Sarathy Combustion and Flame 173, 468-482, 2016 | 162 | 2016 |
| Flux corrected finite volume scheme for preserving scalar boundedness in reacting large-eddy simulations M Herrmann, G Blanquart, V Raman AIAA journal 44 (12), 2879-2886, 2006 | 148* | 2006 |
| Dry powder inhaler device influence on carrier particle performance MJ Donovan, SH Kim, V Raman, HD Smyth Journal of pharmaceutical sciences 101 (3), 1097-1107, 2012 | 140 | 2012 |
| Hybrid finite-volume/transported PDF simulations of a partially premixed methane–air flame V Raman, RO Fox, AD Harvey Combustion and Flame 136 (3), 327-350, 2004 | 121 | 2004 |
| Development of a dynamic model for the subfilter scalar variance using the concept of optimal estimators G Balarac, H Pitsch, V Raman Physics of fluids 20 (3), 2008 | 114 | 2008 |
| Modeling of fine-particle formation in turbulent flames V Raman, RO Fox Annual Review of Fluid Mechanics 48 (1), 159-190, 2016 | 108 | 2016 |
| Mixing and detonation structure in a rotating detonation engine with an axial air inlet T Sato, F Chacon, L White, V Raman, M Gamba Proceedings of the Combustion Institute 38 (3), 3769-3776, 2021 | 105 | 2021 |
| Large-eddy simulation of a supersonic inlet-isolator H Koo, V Raman AIAA Journal 50 (7), 1596-1613, 2012 | 102* | 2012 |
| Numerical simulation of a methane-oxygen rotating detonation rocket engine S Prakash, V Raman, CF Lietz, WA Hargus Jr, SA Schumaker Proceedings of the Combustion Institute 38 (3), 3777-3786, 2021 | 94* | 2021 |
| Emerging trends in numerical simulations of combustion systems V Raman, M Hassanaly Proceedings of the Combustion Institute 37 (2), 2073-2089, 2019 | 85 | 2019 |
| LES/PDF based modeling of soot–turbulence interactions in turbulent flames P Donde, V Raman, ME Mueller, H Pitsch Proceedings of the Combustion Institute 34 (1), 1183-1192, 2013 | 84 | 2013 |
| A quadrature-based LES/transported probability density function approach for modeling supersonic combustion H Koo, P Donde, V Raman Proceedings of the Combustion Institute 33 (2), 2203-2210, 2011 | 83 | 2011 |
| Analysis of the detonation wave structure in a linearized rotating detonation engine S Prakash, R Fiévet, V Raman, J Burr, KH Yu AIAA Journal 58 (12), 5063-5077, 2020 | 82* | 2020 |
| Eulerian transported probability density function sub-filter model for large-eddy simulations of turbulent combustion V Raman, H Pitsch, RO Fox Combustion Theory and Modelling 10 (3), 439-458, 2006 | 82 | 2006 |
| Bayesian analysis of syngas chemistry models K Braman, TA Oliver, V Raman Combustion Theory and Modelling 17 (5), 858-887, 2013 | 70 | 2013 |
| Nonidealities in rotating detonation engines V Raman, S Prakash, M Gamba Annual Review of Fluid Mechanics 55 (1), 639-674, 2023 | 69 | 2023 |
| Detonation structure in ethylene/air-based non-premixed rotating detonation engine T Sato, V Raman Journal of Propulsion and Power 36 (5), 752-762, 2020 | 67* | 2020 |
Heinz PitschRWTH Aachen University, Stanford University, UC San Diego在 itv.rwth-aachen.de 的电子邮件经过验证
