Statistical mechanics of turbulent flows S Heinz, S Heinz Springer, 2003 | 159 | 2003 |
A solution algorithm for the fluid dynamic equations based on a stochastic model for molecular motion P Jenny, M Torrilhon, S Heinz Journal of computational physics 229 (4), 1077-1098, 2010 | 155 | 2010 |
A review of hybrid RANS-LES methods for turbulent flows: Concepts and applications S Heinz Progress in Aerospace Sciences 114, 100597, 2020 | 130 | 2020 |
Mathematical modeling S Heinz Springer, 2011 | 107 | 2011 |
Unified turbulence models for LES and RANS, FDF and PDF simulations S Heinz Theoretical and Computational Fluid Dynamics 21, 99-118, 2007 | 81 | 2007 |
A unified RANS–LES model: Computational development, accuracy and cost H Gopalan, S Heinz, MK Stöllinger Journal of Computational Physics 249, 249-274, 2013 | 78 | 2013 |
On Fokker–Planck equations for turbulent reacting flows. Part 2. Filter density function for large eddy simulation S Heinz Flow, Turbulence and Combustion 70, 153-181, 2003 | 78 | 2003 |
Evaluation of scalar mixing and time scale models in PDF simulations of a turbulent premixed flame M Stöllinger, S Heinz Combustion and Flame 157 (9), 1671-1685, 2010 | 64 | 2010 |
PDF modeling and simulations of pulverized coal combustion–Part 1: Theory and modeling M Stöllinger, B Naud, D Roekaerts, N Beishuizen, S Heinz Combustion and Flame 160 (2), 384-395, 2013 | 59 | 2013 |
PDF modeling and simulations of pulverized coal combustion–Part 2: Application M Stöllinger, B Naud, D Roekaerts, N Beishuizen, S Heinz Combustion and flame 160 (2), 396-410, 2013 | 59 | 2013 |
A model for the reduction of the turbulent energy redistribution by compressibility S Heinz Physics of Fluids 15 (11), 3580-3583, 2003 | 57 | 2003 |
Theory-based Reynolds-averaged Navier–Stokes equations with large eddy simulation capability for separated turbulent flow simulations S Heinz, R Mokhtarpoor, M Stoellinger Physics of Fluids 32 (6), 2020 | 50 | 2020 |
Dynamic unified RANS-LES simulations of high Reynolds number separated flows R Mokhtarpoor, S Heinz, M Stoellinger Physics of Fluids 28 (9), 2016 | 49 | 2016 |
Grid-resolution requirements for large-eddy simulations of the atmospheric boundary layer H Wurps, G Steinfeld, S Heinz Boundary-Layer Meteorology 175 (2), 179-201, 2020 | 48 | 2020 |
Realizability of dynamic subgrid-scale stress models via stochastic analysis S Heinz Walter de Gruyter GmbH & Co. KG 14 (4), 311-329, 2008 | 46 | 2008 |
Dynamic large eddy simulation: Stability via realizability R Mokhtarpoor, S Heinz Physics of Fluids 29 (10), 2017 | 45 | 2017 |
Realizable versus non-realizable dynamic subgrid-scale stress models S Heinz, H Gopalan Physics of Fluids 24 (11), 2012 | 39 | 2012 |
PDF modeling and simulation of premixed turbulent combustion M Stöllinger, S Heinz Walter de Gruyter GmbH & Co. KG 14 (4), 343-377, 2008 | 37 | 2008 |
On Fokker–Planck equations for turbulent reacting flows. Part 1. Probability density function for Reynolds-averaged Navier–Stokes equations S Heinz Flow, turbulence and combustion 70, 115-152, 2003 | 36 | 2003 |
The large eddy simulation capability of Reynolds-averaged Navier-Stokes equations: Analytical results S Heinz Physics of Fluids 31 (2), 2019 | 35 | 2019 |