An eddy-viscosity subgrid-scale model for turbulent shear flow: Algebraic theory and applications AW Vreman Physics of fluids 16 (10), 3670-3681, 2004 | 1439 | 2004 |

Large-eddy simulation of the turbulent mixing layer B Vreman, B Geurts, H Kuerten Journal of Fluid Mechanics 339, 357-390, 1997 | 650 | 1997 |

On the formulation of the dynamic mixed subgrid‐scale model B Vreman, B Geurts, H Kuerten Physics of Fluids 6 (12), 4057-4059, 1994 | 403 | 1994 |

Compressible mixing layer growth rate and turbulence characteristics AW Vreman, ND Sandham, KH Luo J. Fluid Mech 320, 235-258, 1996 | 396 | 1996 |

Premixed and nonpremixed generated manifolds in large-eddy simulation of Sandia flame D and F AW Vreman, BA Albrecht, JA Van Oijen, LPH De Goey, RJM Bastiaans Combustion and Flame 153 (3), 394-416, 2008 | 355 | 2008 |

Realizability conditions for the turbulent stress tensor in large-eddy simulation B Vreman, B Geurts, H Kuerten Journal of Fluid Mechanics 278, 351-362, 1994 | 328 | 1994 |

Subgrid-modelling in LES of compressible flow B Vreman, B Geurts, H Kuerten Applied scientific research 54, 191-203, 1995 | 260 | 1995 |

A priori tests of large eddy simulation of the compressible plane mixing layer B Vreman, B Geurts, H Kuerten Journal of engineering mathematics 29 (4), 299-327, 1995 | 255 | 1995 |

Direct and large-eddy simulation of the compressible turbulent mixing layer AW Vreman PhD Thesis, University of Twente, 1995 | 246 | 1995 |

Comparison of direct numerical simulation databases of turbulent channel flow at Reτ=180 AW Vreman, JGM Kuerten Physics of Fluids (1994-present) 26 (1), 015102, 2014 | 203 | 2014 |

Large-eddy simulation of the temporal mixing layer using the Clark model B Vreman, B Geurts, H Kuerten Theoretical and Computational Fluid Dynamics 8 (4), 309-324, 1996 | 195 | 1996 |

COMPARISION of numerical schemes in large‐eddy simulation of the temporal mixing layer B Vreman, B Geurts, H Kuerten International journal for numerical methods in fluids 22 (4), 297-311, 1996 | 194 | 1996 |

Can turbophoresis be predicted by large-eddy simulation? JGM Kuerten, AW Vreman Physics of Fluids 17 (1), 011701-011701-4, 2005 | 165 | 2005 |

Turbulence characteristics of particle-laden pipe flow AW Vreman Journal of fluid mechanics 584, 235-279, 2007 | 164 | 2007 |

Two-and four-way coupled Euler–Lagrangian large-eddy simulation of turbulent particle-laden channel flow B Vreman, BJ Geurts, NG Deen, JAM Kuipers, JGM Kuerten Flow, turbulence and combustion 82, 47-71, 2009 | 137 | 2009 |

The filtering analog of the variational multiscale method in large-eddy simulation AW Vreman Physics of Fluids 15 (8), L61-L64, 2003 | 128 | 2003 |

Turbulence attenuation in particle-laden flow in smooth and rough channels AW Vreman Journal of Fluid Mechanics 773, 103-136, 2015 | 104 | 2015 |

A basic population balance model for fluid bed spray granulation AW Vreman, CE Van Lare, MJ Hounslow Chemical Engineering Science 64 (21), 4389-4398, 2009 | 97 | 2009 |

Subgrid scale modeling in large-eddy simulation of turbulent combustion using premixed flamelet chemistry AW Vreman, JA Van Oijen, LPH De Goey, RJM Bastiaans Flow, Turbulence and Combustion 82, 511-535, 2009 | 91 | 2009 |

Ohmic resistance in zero gap alkaline electrolysis with a Zirfon diaphragm MT de Groot, AW Vreman Electrochimica Acta 369, 137684, 2021 | 85 | 2021 |