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An unconditionally energy stable finite element scheme for a nonlinear fluid–fluid interaction model

Wei Li, Pengzhan Huang, Yinnian He

2023IMA Journal of Numerical Analysis17 citationsDOI

Abstract

Abstract In this paper, we design a decoupled scheme for solving a fluid–fluid interaction problem, which includes two Navier–Stokes equations coupled by some nonlinear interface conditions. Compared with two decoupled schemes proposed by Connors et al. (2012, Decoupled time stepping methods for fluid–fluid interaction. SIAM J. Numer. Anal., 50, 1297–1319) for the fluid–fluid interaction problem, we deal with these nonlinear interface conditions by applying explicit scheme. The presented fully discrete scheme is a combination of a mixed finite element approximation for spatial discretization, the first-order backward Euler scheme for temporal discretization and explicit treatment for the interface conditions and the nonlinear terms. Moreover, the unconditional energy stability is established and error estimate for the fully discrete scheme is also showed. Finally, some numerical experiments are provided to verify the theoretical results, which illustrate the accuracy and efficiency of the presented scheme.

Topics & Concepts

DiscretizationNonlinear systemMathematicsFinite element methodApplied mathematicsFluid–structure interactionScheme (mathematics)Euler's formulaStability (learning theory)Energy (signal processing)Mathematical analysisComputer sciencePhysicsMachine learningThermodynamicsStatisticsQuantum mechanicsAdvanced Numerical Methods in Computational MathematicsDifferential Equations and Numerical MethodsAdvanced Mathematical Modeling in Engineering
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