Discrete-velocity models and numerical schemes for the Boltzmann-BGK equation in plane and axisymmetric geometries L Mieussens Journal of Computational Physics 162 (2), 429-466, 2000 | 347 | 2000 |

Discrete velocity model and implicit scheme for the BGK equation of rarefied gas dynamics L Mieussens Mathematical Models and Methods in Applied Sciences 10 (08), 1121-1149, 2000 | 212 | 2000 |

A new asymptotic preserving scheme based on micro-macro formulation for linear kinetic equations in the diffusion limit M Lemou, L Mieussens SIAM Journal on Scientific Computing 31 (1), 334-368, 2008 | 190 | 2008 |

Uniformly stable numerical schemes for the Boltzmann equation preserving the compressible Navier–Stokes asymptotics M Bennoune, M Lemou, L Mieussens Journal of Computational Physics 227 (8), 3781-3803, 2008 | 159 | 2008 |

Numerical comparison of Bhatnagar–Gross–Krook models with proper Prandtl number L Mieussens, H Struchtrup Physics of Fluids 16 (8), 2797-2813, 2004 | 110 | 2004 |

A smooth transition model between kinetic and hydrodynamic equations P Degond, S Jin, L Mieussens Journal of Computational Physics 209 (2), 665-694, 2005 | 89 | 2005 |

A multiscale kinetic–fluid solver with dynamic localization of kinetic effects P Degond, G Dimarco, L Mieussens Journal of Computational Physics 229 (13), 4907-4933, 2010 | 70 | 2010 |

Locally refined discrete velocity grids for stationary rarefied flow simulations C Baranger, J Claudel, N Hérouard, L Mieussens Journal of Computational Physics 257, 572-593, 2014 | 63 | 2014 |

Macroscopic fluid models with localized kinetic upscaling effects P Degond, JG Liu, L Mieussens Multiscale Modeling & Simulation 5 (3), 940-979, 2006 | 60 | 2006 |

On the asymptotic preserving property of the unified gas kinetic scheme for the diffusion limit of linear kinetic models L Mieussens Journal of Computational Physics 253, 138-156, 2013 | 59 | 2013 |

Analysis of an asymptotic preserving scheme for linear kinetic equations in the diffusion limit JG Liu, L Mieussens SIAM Journal on Numerical Analysis 48 (4), 1474-1491, 2010 | 53 | 2010 |

Numerical simulations of rarefied gases in curved channels: Thermal creep, circulating flow, and pumping effect K Aoki, P Degond, L Mieussens Communications in Computational Physics 6 (5), 919, 2009 | 52 | 2009 |

A moving interface method for dynamic kinetic–fluid coupling P Degond, G Dimarco, L Mieussens Journal of Computational Physics 227 (2), 1176-1208, 2007 | 51 | 2007 |

A Fokker–Planck model of the Boltzmann equation with correct Prandtl number J Mathiaud, L Mieussens Journal of Statistical Physics 162 (2), 397-414, 2016 | 41 | 2016 |

Local discrete velocity grids for deterministic rarefied flow simulations S Brull, L Mieussens Journal of Computational Physics 266, 22-46, 2014 | 35 | 2014 |

A survey of deterministic solvers for rarefied flows L Mieussens AIP Conference Proceedings 1628 (1), 943-951, 2014 | 34 | 2014 |

A diffusion model for rarefied flows in curved channels K Aoki, P Degond, L Mieussens, S Takata, H Yoshida Multiscale Modeling & Simulation 6 (4), 1281-1316, 2008 | 32 | 2008 |

A conservative and entropic discrete-velocity model for rarefied polyatomic gases B Dubroca, L Mieussens ESAIM: Proceedings 10, 127-139, 2001 | 32 | 2001 |

Implicit Schemes for the Fokker--Planck--Landau Equation M Lemou, L Mieussens SIAM Journal on Scientific Computing 27 (3), 809-830, 2005 | 29 | 2005 |

Convergence of a discrete-velocity model for the Boltzmann-BGK equation L Mieussens Computers & Mathematics with Applications 41 (1-2), 83-96, 2001 | 29 | 2001 |