| An explicit reduced mechanism for H2–air combustion P Boivin, C Jiménez, AL Sánchez, FA Williams Proceedings of the Combustion Institute 33 (1), 517-523, 2011 | 174 | 2011 |
| A general formulation for cavitating, boiling and evaporating flows R Saurel, P Boivin, O Le Métayer Computers & Fluids 128, 53-64, 2016 | 114 | 2016 |
| Hybrid recursive regularized thermal lattice Boltzmann model for high subsonic compressible flows Y Feng, P Boivin, J Jacob, P Sagaut Journal of Computational Physics 394, 82-99, 2019 | 89 | 2019 |
| Simulation of a supersonic hydrogen–air autoignition-stabilized flame using reduced chemistry P Boivin, A Dauptain, C Jiménez, B Cuenot Combustion and Flame 159 (4), 1779-1790, 2012 | 86 | 2012 |
| A four-step reduced mechanism for syngas combustion P Boivin, C Jiménez, AL Sánchez, FA Williams Combustion and Flame 158 (6), 1059-1063, 2011 | 83 | 2011 |
| A simple and fast phase transition relaxation solver for compressible multicomponent two-phase flows A Chiapolino, P Boivin, R Saurel Computers & Fluids 150, 31-45, 2017 | 63 | 2017 |
| A pressure-based regularized lattice-Boltzmann method for the simulation of compressible flows G Farag, S Zhao, T Coratger, P Boivin, G Chiavassa, P Sagaut Physics of Fluids 32 (6), 066106, 2020 | 44 | 2020 |
| A simple phase transition relaxation solver for liquid–vapor flows A Chiapolino, P Boivin, R Saurel International Journal for Numerical Methods in Fluids 83 (7), 583-605, 2017 | 42 | 2017 |
| Explicit analytic prediction for hydrogen–oxygen ignition times at temperatures below crossover P Boivin, AL Sánchez, FA Williams Combustion and Flame 159 (2), 748-752, 2012 | 42 | 2012 |
| A Lattice-Boltzmann model for low-Mach reactive flows Y Feng, M Tayyab, P Boivin Combustion and Flame 196, 249-254, 2018 | 39 | 2018 |
| Four-step and three-step systematically reduced chemistry for wide-range H2–air combustion problems P Boivin, AL Sánchez, FA Williams Combustion and flame 160 (1), 76-82, 2013 | 38 | 2013 |
| Reduced-kinetic mechanisms for hydrogen and syngas combustion including autoignition P Boivin | 36 | 2011 |
| A new formulation for two-wave Riemann solver accurate at contact interfaces X Deng, P Boivin, F Xiao Physics of Fluids 31 (4), 046102, 2019 | 30 | 2019 |
| Hybrid regularized lattice-Boltzmann modelling of premixed and non-premixed combustion processes M Tayyab, S Zhao, Y Feng, P Boivin Combustion and Flame 211, 173-184, 2020 | 28 | 2020 |
| Consistency study of lattice-Boltzmann schemes macroscopic limit G Farag, S Zhao, G Chiavassa, P Boivin Physics of Fluids 33 (3), 037101, 2021 | 27 | 2021 |
| Hybrid recursive regularized lattice Boltzmann simulation of humid air with application to meteorological flows Y Feng, P Boivin, J Jacob, P Sagaut Physical Review E 100 (2), 023304, 2019 | 26 | 2019 |
| Toward fully conservative hybrid lattice Boltzmann methods for compressible flows S Zhao, G Farag, P Boivin, P Sagaut Physics of Fluids 32 (12), 126118, 2020 | 20 | 2020 |
| Analytical prediction of syngas induction times P Boivin, AL Sánchez, FA Williams Combustion and Flame 176, 489-499, 2017 | 20 | 2017 |
| A unified hybrid lattice-Boltzmann method for compressible flows: Bridging between pressure-based and density-based methods G Farag, T Coratger, G Wissocq, S Zhao, P Boivin, P Sagaut Physics of Fluids 33 (8), 086101, 2021 | 18 | 2021 |
| A thermodynamic closure for the simulation of multiphase reactive flows P Boivin, MA Cannac, O Le Métayer International Journal of Thermal Sciences 137, 640-649, 2019 | 18 | 2019 |
Song ZHAOResearch engineer, M2P2-CNRSVerified email at univ-amu.fr
