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Coarse grained simulations of shock-driven turbulent material mixing

Publication ,  Journal Article
Grinstein, FF; Saenz, JA; Germano, M
Published in: Physics of Fluids
March 1, 2021

We revisit coarse-grained simulation strategies for turbulent material mixing applications involving shock-driven turbulence in the context of the Radiation Adaptive Grid Eulerian (xRAGE) hydrodynamics and Besnard-Harlow-Rauenzahn (BHR) Reynolds-averaged Navier-Stokes codes, using newly available Low-Mach-Corrected (LMC) xRAGE hydrodynamics. Impact assessments are based on comparisons with a relevant shock-tube experiment for which turbulent mixing and velocity data are available. xRAGE Implicit Large-Eddy Simulation (ILES) and a recently proposed xRAGE-BHR bridging paradigm are tested. Bridging models turbulent stresses dynamically, based on decomposing the full stress into modeled and resolved components, using a differential filter as a secondary filtering operation to define the resolved part, and additionally requiring the resolved stress to approach the full stress with grid resolution refinement to ensure realizability of the bridging-based large-eddy simulation. Much improved scale-resolving with LMC-xRAGE ILES and with dynamic LMC-xRAGE/BHR bridging enables higher simulated mixing and turbulence levels on coarser grids. For the tested planar shock-tube case, the more-accurate models can achieve the same level of accuracy with less resolution than required with the highest-fidelity turbulence simulation models typically used at scale with default xRAGE hydrodynamics; two-levels of grid-coarsening savings can be thus achieved for the mixing prediction in these comparisons: one associated with the more-accurate LMC xRAGE hydrodynamics and an additional one from using the dynamic xRAGE-BHR bridging.

Duke Scholars

Published In

Physics of Fluids

DOI

EISSN

1089-7666

ISSN

1070-6631

Publication Date

March 1, 2021

Volume

33

Issue

3

Related Subject Headings

  • Fluids & Plasmas
  • 51 Physical sciences
  • 49 Mathematical sciences
  • 40 Engineering
  • 09 Engineering
  • 02 Physical Sciences
  • 01 Mathematical Sciences
 

Citation

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ICMJE
MLA
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Grinstein, F. F., Saenz, J. A., & Germano, M. (2021). Coarse grained simulations of shock-driven turbulent material mixing. Physics of Fluids, 33(3). https://doi.org/10.1063/5.0039525
Grinstein, F. F., J. A. Saenz, and M. Germano. “Coarse grained simulations of shock-driven turbulent material mixing.” Physics of Fluids 33, no. 3 (March 1, 2021). https://doi.org/10.1063/5.0039525.
Grinstein FF, Saenz JA, Germano M. Coarse grained simulations of shock-driven turbulent material mixing. Physics of Fluids. 2021 Mar 1;33(3).
Grinstein, F. F., et al. “Coarse grained simulations of shock-driven turbulent material mixing.” Physics of Fluids, vol. 33, no. 3, Mar. 2021. Scopus, doi:10.1063/5.0039525.
Grinstein FF, Saenz JA, Germano M. Coarse grained simulations of shock-driven turbulent material mixing. Physics of Fluids. 2021 Mar 1;33(3).

Published In

Physics of Fluids

DOI

EISSN

1089-7666

ISSN

1070-6631

Publication Date

March 1, 2021

Volume

33

Issue

3

Related Subject Headings

  • Fluids & Plasmas
  • 51 Physical sciences
  • 49 Mathematical sciences
  • 40 Engineering
  • 09 Engineering
  • 02 Physical Sciences
  • 01 Mathematical Sciences