| Towards an extended scalar dissipation equation for turbulent premixed combustion A Mura, R Borghi Combustion and flame 133 (1-2), 193-196, 2003 | 132 | 2003 |
| Experimental and numerical analysis of stratified turbulent V-shaped flames V Robin, A Mura, M Champion, O Degardin, B Renou, M Boukhalfa Combustion and flame 153 (1-2), 288-315, 2008 | 125 | 2008 |
| A new model for turbulent flows with large density fluctuations: Application to liquid atomization FX Demoulin, PA Beau, G Blokkeel, A Mura, R Borghi Atomization and Sprays 17 (4), 2007 | 121 | 2007 |
| Modeling of scalar dissipation in partially premixed turbulent flames A Mura, V Robin, M Champion Combustion and flame 149 (1-2), 217-224, 2007 | 103 | 2007 |
| Highly resolved numerical simulation of combustion in supersonic hydrogen–air coflowing jets Y Moule, V Sabelnikov, A Mura Combustion and Flame 161 (10), 2647-2668, 2014 | 96 | 2014 |
| Scalar dissipation rate approach to reaction rate closure N Chakraborty, M Champion, A Mura, N Swaminathan Turbulent premixed flames, 2011 | 88 | 2011 |
| A detailed verification procedure for compressible reactive multicomponent Navier–Stokes solvers PJM Ferrer, R Buttay, G Lehnasch, A Mura Computers & Fluids 89, 88-110, 2014 | 81 | 2014 |
| A multi-Dirac presumed PDF model for turbulent reactive flows with variable equivalence ratio V Robin, A Mura, M Champion, P Plion Combustion science and technology 178 (10-11), 1843-1870, 2006 | 78 | 2006 |
| Modelling of the correlation between velocity and reactive scalar gradients in turbulent premixed flames based on DNS data A Mura, K Tsuboi, T Hasegawa Combustion Theory and Modelling 12 (4), 671-698, 2008 | 76 | 2008 |
| Characterization of the local flame structure and the flame surface density for freely propagating premixed flames at various Lewis numbers B Renou, A Mura, E Samson, A Boukhalfa Combustion science and technology 174 (4), 143-179, 2002 | 73 | 2002 |
| Experimental analysis of propagation regimes during the autoignition of a fully premixed methane–air mixture in the presence of temperature inhomogeneities C Strozzi, A Mura, J Sotton, M Bellenoue Combustion and Flame 159 (11), 3323-3341, 2012 | 71 | 2012 |
| A combined ghost-point-forcing/direct-forcing immersed boundary method (IBM) for compressible flow simulations R Boukharfane, FHE Ribeiro, Z Bouali, A Mura Computers & Fluids 162, 91-112, 2018 | 64 | 2018 |
| Characterization of a two-dimensional temperature field within a rapid compression machine using a toluene planar laser-induced fluorescence imaging technique C Strozzi, J Sotton, A Mura, M Bellenoue Measurement Science and Technology 20 (12), 125403, 2009 | 60 | 2009 |
| Numerical simulation of supersonic nonpremixed turbulent combustion in a scramjet combustor model A Mura, JF Izard Journal of Propulsion and Power 26 (4), 858-868, 2010 | 56 | 2010 |
| Direct and indirect thermal expansion effects in turbulent premixed flames V Robin, A Mura, M Champion Journal of fluid mechanics 689, 149-182, 2011 | 55 | 2011 |
| Small scale features of velocity and scalar fields in turbulent premixed flames A Mura, V Robin, M Champion, T Hasegawa Flow, turbulence and combustion 82, 339-358, 2009 | 55 | 2009 |
| A unified PDF-flamelet model for turbulent premixed combustion A Mura, F Galzin, R Borghi Combustion Science and Technology 175 (9), 1573-1609, 2003 | 53 | 2003 |
| Compressibility and heat release effects in high-speed reactive mixing layers I.: Growth rates and turbulence characteristics PJM Ferrer, G Lehnasch, A Mura Combustion and Flame 180, 284-303, 2017 | 51 | 2017 |
| Application of the method of manufactured solutions to the verification of a pressure-based finite-volume numerical scheme JM Vedovoto, A da Silveira Neto, A Mura, LFF da Silva Computers & Fluids 51 (1), 85-99, 2011 | 46 | 2011 |
| Computational fluid dynamics investigation of a Mach 12 scramjet engine Y Moule, V Sabel’nikov, A Mura, M Smart Journal of Propulsion and Power 30 (2), 461-473, 2014 | 45 | 2014 |
