FLUID-FLUID INTERACTION PROBLEMS AT HIGH REYNOLDS NUMBERS: REDUCING THE MODELING ERROR WITH LES-C

Mustafa Aggul; Alexander E. Labovsky; Eda Onal; Kyle J. Schwiebert

doi:10.1137/22M1494269

FLUID-FLUID INTERACTION PROBLEMS AT HIGH REYNOLDS NUMBERS: REDUCING THE MODELING ERROR WITH LES-C

Mustafa Aggul
, Alexander E. Labovsky
, Eda Onal
, Kyle J. Schwiebert

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

We consider a fluid-fluid interaction problem, where two flows (with high Reynolds numbers for one or both of these flows) are coupled through a joint interface. A nonlinear coupling equation, known as the rigid lid condition, creates an extra level of difficulty, typical for atmosphere-ocean problems. We propose a novel turbulence model, NS-\omega -C, from the recently introduced family of LES-C (large eddy simulation with correction) models. Combining it with the so-called geometric averaging (GA) partitioning method, we obtain the NS-\omega -C-GA model that is shown to possess several key properties. First, the preexisting solvers for the subdomains can be used, which is critical, e.g., for atmosphere-ocean applications. Second, the LES-C turbulence models use defect correction to efficiently reduce the modeling error of the corresponding LES models; we demonstrate numerically that the NS-\omega -C model outperforms its LES counterpart, the NS-\omega model. It has also been shown recently that it is favorable for an LES model to have the nonfiltered velocity in the interface terms. The NS-\omega -C-GA model possesses this important property; we also show it to be stable and have optimal convergence properties.

Original language	English
Pages (from-to)	707-732
Number of pages	26
Journal	SIAM Journal on Numerical Analysis
Volume	61
Issue number	2
DOIs	https://doi.org/10.1137/22M1494269
State	Published - 2023
Externally published	Yes

Funding

*Received by the editors May 4, 2022; accepted for publication (in revised form) September 9, 2022; published electronically April 3, 2023. https://doi.org/10.1137/22M1494269 Funding: The work of the fourth author was partially supported by the Michigan Space Grant Consortium grant 80NSSC20M0124. dagger Department of Mathematics, Hacettepe University, Ankara 06800, Turkey (mustafaaggul@ hacettepe.edu.tr, [email protected]). ddagger Department of Mathematical Sciences, Michigan Technological University, Houghton, MI 49931 USA ([email protected], [email protected]).

Keywords

Navier-Stokes equations
computational fluid dynamics
fluid-fluid interaction
incompressible flow
turbulence modeling

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10.1137/22M1494269

Cite this

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title = "FLUID-FLUID INTERACTION PROBLEMS AT HIGH REYNOLDS NUMBERS: REDUCING THE MODELING ERROR WITH LES-C",

abstract = "We consider a fluid-fluid interaction problem, where two flows (with high Reynolds numbers for one or both of these flows) are coupled through a joint interface. A nonlinear coupling equation, known as the rigid lid condition, creates an extra level of difficulty, typical for atmosphere-ocean problems. We propose a novel turbulence model, NS-\textbackslash{}omega -C, from the recently introduced family of LES-C (large eddy simulation with correction) models. Combining it with the so-called geometric averaging (GA) partitioning method, we obtain the NS-\textbackslash{}omega -C-GA model that is shown to possess several key properties. First, the preexisting solvers for the subdomains can be used, which is critical, e.g., for atmosphere-ocean applications. Second, the LES-C turbulence models use defect correction to efficiently reduce the modeling error of the corresponding LES models; we demonstrate numerically that the NS-\textbackslash{}omega -C model outperforms its LES counterpart, the NS-\textbackslash{}omega model. It has also been shown recently that it is favorable for an LES model to have the nonfiltered velocity in the interface terms. The NS-\textbackslash{}omega -C-GA model possesses this important property; we also show it to be stable and have optimal convergence properties.",

keywords = "Navier-Stokes equations, computational fluid dynamics, fluid-fluid interaction, incompressible flow, turbulence modeling",

author = "Mustafa Aggul and Labovsky, \{Alexander E.\} and Eda Onal and Schwiebert, \{Kyle J.\}",

note = "Publisher Copyright: {\textcopyright} 2023 Society for Industrial and Applied Mathematics.",

year = "2023",

doi = "10.1137/22M1494269",

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T2 - REDUCING THE MODELING ERROR WITH LES-C

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AU - Labovsky, Alexander E.

AU - Onal, Eda

AU - Schwiebert, Kyle J.

PY - 2023

Y1 - 2023

N2 - We consider a fluid-fluid interaction problem, where two flows (with high Reynolds numbers for one or both of these flows) are coupled through a joint interface. A nonlinear coupling equation, known as the rigid lid condition, creates an extra level of difficulty, typical for atmosphere-ocean problems. We propose a novel turbulence model, NS-\omega -C, from the recently introduced family of LES-C (large eddy simulation with correction) models. Combining it with the so-called geometric averaging (GA) partitioning method, we obtain the NS-\omega -C-GA model that is shown to possess several key properties. First, the preexisting solvers for the subdomains can be used, which is critical, e.g., for atmosphere-ocean applications. Second, the LES-C turbulence models use defect correction to efficiently reduce the modeling error of the corresponding LES models; we demonstrate numerically that the NS-\omega -C model outperforms its LES counterpart, the NS-\omega model. It has also been shown recently that it is favorable for an LES model to have the nonfiltered velocity in the interface terms. The NS-\omega -C-GA model possesses this important property; we also show it to be stable and have optimal convergence properties.

AB - We consider a fluid-fluid interaction problem, where two flows (with high Reynolds numbers for one or both of these flows) are coupled through a joint interface. A nonlinear coupling equation, known as the rigid lid condition, creates an extra level of difficulty, typical for atmosphere-ocean problems. We propose a novel turbulence model, NS-\omega -C, from the recently introduced family of LES-C (large eddy simulation with correction) models. Combining it with the so-called geometric averaging (GA) partitioning method, we obtain the NS-\omega -C-GA model that is shown to possess several key properties. First, the preexisting solvers for the subdomains can be used, which is critical, e.g., for atmosphere-ocean applications. Second, the LES-C turbulence models use defect correction to efficiently reduce the modeling error of the corresponding LES models; we demonstrate numerically that the NS-\omega -C model outperforms its LES counterpart, the NS-\omega model. It has also been shown recently that it is favorable for an LES model to have the nonfiltered velocity in the interface terms. The NS-\omega -C-GA model possesses this important property; we also show it to be stable and have optimal convergence properties.

KW - Navier-Stokes equations

KW - computational fluid dynamics

KW - fluid-fluid interaction

KW - incompressible flow

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ER -

FLUID-FLUID INTERACTION PROBLEMS AT HIGH REYNOLDS NUMBERS: REDUCING THE MODELING ERROR WITH LES-C

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