Modeling of radiation and nitric oxide formation in turbulent nonpremixed flames using a flamelet/progress variable formulation M Ihme, H Pitsch Physics of Fluids 20 (5), 2008 | 388 | 2008 |
Prediction of local extinction and re-ignition effects in non-premixed turbulent combustion using a flamelet/progress variable approach M Ihme, CM Cha, H Pitsch Proceedings of the Combustion Institute 30 (1), 793-800, 2005 | 336 | 2005 |
Prediction of extinction and reignition in nonpremixed turbulent flames using a flamelet/progress variable model: 2. Application in LES of Sandia flames D and E M Ihme, H Pitsch Combustion and flame 155 (1-2), 90-107, 2008 | 333 | 2008 |
Prediction of autoignition in a lifted methane/air flame using an unsteady flamelet/progress variable model M Ihme, YC See Combustion and Flame 157 (10), 1850-1862, 2010 | 257 | 2010 |
Prediction of extinction and reignition in nonpremixed turbulent flames using a flamelet/progress variable model: 1. A priori study and presumed PDF closure M Ihme, H Pitsch Combustion and flame 155 (1-2), 70-89, 2008 | 237 | 2008 |
Regularization of reaction progress variable for application to flamelet-based combustion models M Ihme, L Shunn, J Zhang Journal of Computational Physics 231 (23), 7715-7721, 2012 | 218 | 2012 |
LES flamelet modeling of a three-stream MILD combustor: Analysis of flame sensitivity to scalar inflow conditions M Ihme, YC See Proceedings of the Combustion Institute 33 (1), 1309-1317, 2011 | 214 | 2011 |
Optimal artificial neural networks and tabulation methods for chemistry representation in LES of a bluff-body swirl-stabilized flame M Ihme, C Schmitt, H Pitsch Proceedings of the Combustion Institute 32 (1), 1527-1535, 2009 | 189 | 2009 |
Fuel effects on lean blow-out in a realistic gas turbine combustor L Esclapez, PC Ma, E Mayhew, R Xu, S Stouffer, T Lee, H Wang, M Ihme Combustion and Flame 181, 82-99, 2017 | 187 | 2017 |
An entropy-stable hybrid scheme for simulations of transcritical real-fluid flows PC Ma, Y Lv, M Ihme Journal of Computational Physics 340, 330-357, 2017 | 182 | 2017 |
Combustion and engine-core noise M Ihme Annual Review of Fluid Mechanics 49 (1), 277-310, 2017 | 142 | 2017 |
Combustion machine learning: Principles, progress and prospects M Ihme, WT Chung, AA Mishra Progress in Energy and Combustion Science 91, 101010, 2022 | 141 | 2022 |
An unsteady/flamelet progress variable method for LES of nonpremixed turbulent combustion H Pitsch, M Ihme 43rd AIAA Aerospace Sciences Meeting and Exhibit, 557, 2005 | 124 | 2005 |
Large-eddy simulation of a jet-in-hot-coflow burner operating in the oxygen-diluted combustion regime M Ihme, J Zhang, G He, B Dally Flow, turbulence and combustion 89, 449-464, 2012 | 119 | 2012 |
Ignition regimes in rapid compression machines KP Grogan, SS Goldsborough, M Ihme Combustion and Flame 162 (8), 3071-3080, 2015 | 109 | 2015 |
Compositional inhomogeneities as a source of indirect combustion noise L Magri, J O’Brien, M Ihme Journal of Fluid Mechanics 799, R4, 2016 | 98 | 2016 |
Analysis of segregation and bifurcation in turbulent spray flames: A 3D counterflow configuration A Vié, B Franzelli, Y Gao, T Lu, H Wang, M Ihme Proceedings of the Combustion Institute 35 (2), 1675-1683, 2015 | 95 | 2015 |
Discontinuous Galerkin method for multicomponent chemically reacting flows and combustion Y Lv, M Ihme Journal of Computational Physics 270, 105-137, 2014 | 95 | 2014 |
Seven questions about supercritical fluids-towards a new fluid state diagram D Banuti, M Raju, PC Ma, M Ihme, JP Hickey 55th AIAA Aerospace Sciences Meeting, 1106, 2017 | 89 | 2017 |
Widom lines in binary mixtures of supercritical fluids M Raju, DT Banuti, PC Ma, M Ihme Scientific reports 7 (1), 3027, 2017 | 88 | 2017 |