TY - JOUR
T1 - FLUID-FLUID INTERACTION PROBLEMS AT HIGH REYNOLDS NUMBERS
T2 - REDUCING THE MODELING ERROR WITH LES-C
AU - Aggul, Mustafa
AU - Labovsky, Alexander E.
AU - Onal, Eda
AU - Schwiebert, Kyle J.
N1 - Publisher Copyright:
© 2023 Society for Industrial and Applied Mathematics.
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 - computational fluid dynamics
KW - fluid-fluid interaction
KW - incompressible flow
KW - Navier-Stokes equations
KW - turbulence modeling
UR - http://www.scopus.com/inward/record.url?scp=85153342750&partnerID=8YFLogxK
U2 - 10.1137/22M1494269
DO - 10.1137/22M1494269
M3 - Article
AN - SCOPUS:85153342750
SN - 0036-1429
VL - 61
SP - 707
EP - 732
JO - SIAM Journal on Numerical Analysis
JF - SIAM Journal on Numerical Analysis
IS - 2
ER -