Stefan Turek
Stefan Turek
TU Dortmund
Bestätigte E-Mail-Adresse bei
Zitiert von
Zitiert von
Benchmark computations of laminar flow around a cylinder
M Schäfer, S Turek, F Durst, E Krause, R Rannacher
Flow simulation with high-performance computers II, 547-566, 1996
Simple nonconforming quadrilateral Stokes element
R Rannacher, S Turek
Numerical Methods for Partial Differential Equations 8 (2), 97-111, 1992
Efficient Solvers for Incompressible Flow Problems: An Algorithmic and Computational Approache
S Turek
Springer Science & Business Media, 1999
Artificial boundaries and flux and pressure conditions for the incompressible Navier–Stokes equations
JG Heywood, R Rannacher, S Turek
International Journal for numerical methods in fluids 22 (5), 325-352, 1996
Proposal for numerical benchmarking of fluid-structure interaction between an elastic object and laminar incompressible flow
S Turek, J Hron
Fluid-structure interaction, 371-385, 2006
Quantitative benchmark computations of two‐dimensional bubble dynamics
SR Hysing, S Turek, D Kuzmin, N Parolini, E Burman, S Ganesan, ...
International Journal for Numerical Methods in Fluids 60 (11), 1259-1288, 2009
Internal circulation within the liquid slugs of a liquid− liquid slug-flow capillary microreactor
MN Kashid, I Gerlach, S Goetz, J Franzke, JF Acker, F Platte, DW Agar, ...
Industrial & engineering chemistry research 44 (14), 5003-5010, 2005
Swimming by reciprocal motion at low Reynolds number
T Qiu, TC Lee, AG Mark, KI Morozov, R Münster, O Mierka, S Turek, ...
Nature communications 5 (1), 1-8, 2014
A monolithic FEM/multigrid solver for an ALE formulation of fluid-structure interaction with applications in biomechanics
J Hron, S Turek
Fluid-structure interaction, 146-170, 2006
Benchmark computations based on lattice-Boltzmann, finite element and finite volume methods for laminar flows
S Geller, M Krafczyk, J Tölke, S Turek, J Hron
Computers & fluids 35 (8-9), 888-897, 2006
Flux-corrected transport: principles, algorithms, and applications
D Kuzmin, R Löhner, S Turek
Springer Science & Business Media, 2012
Flux correction tools for finite elements
D Kuzmin, S Turek
Journal of Computational Physics 175 (2), 525-558, 2002
A comparative study of time‐stepping techniques for the incompressible Navier‐Stokes equations: from fully implicit non‐linear schemes to semi‐implicit projection methods
S Turek
International Journal for Numerical Methods in Fluids 22 (10), 987-1011, 1996
Direct numerical simulation of particulate flow via multigrid FEM techniques and the fictitious boundary method
D Wan, S Turek
International Journal for Numerical Methods in Fluids 51 (5), 531-566, 2006
Performance and accuracy of hardware-oriented native-, emulated-and mixed-precision solvers in FEM simulations
D Göddeke, R Strzodka, S Turek
International Journal of Parallel, Emergent and Distributed Systems 22 (4 …, 2007
Exploring weak scalability for FEM calculations on a GPU-enhanced cluster
D Göddeke, R Strzodka, J Mohd-Yusof, P McCormick, SHM Buijssen, ...
Parallel Computing 33 (10-11), 685-699, 2007
High-resolution FEM-TVD schemes based on a fully multidimensional flux limiter
D Kuzmin, S Turek
Journal of Computational Physics 198 (1), 131-158, 2004
On the implementation of the k-[epsilon] turbulence model in incompressible flow solvers based on a finite element discretization
D Kuzmin, O Mierka, S Turek
Univ., 2007
Hemodynamical flows
GP Galdi, R Rannacher, AM Robertson, S Turek
Delhi Book Store, 2008
Using GPUs to improve multigrid solver performance on a cluster
D Göddeke, R Strzodka, J Mohd-Yusof, PS McCormick, H Wobker, ...
International Journal of Computational Science and Engineering 4 (1), 36, 2008
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