Dmitri Kuzmin scite author profile

Benchmark configurations for quantitative validation and comparison of incompressible interfacial flow codes, which model two-dimensional bubbles rising in liquid columns, are proposed. The benchmark quantities: circularity, center of mass, and mean rise velocity are defined and measured to monitor convergence toward a reference solution. Comprehensive studies are undertaken by three independent research groups, two representing Eulerian level set finite-element codes and one representing an arbitrary Lagrangian-Eulerian moving grid approach.\ud The first benchmark test case considers a bubble with small density and viscosity ratios, which undergoes moderate shape deformation. The results from all codes agree very well allowing for target reference values to be established. For the second test case, a bubble with a very low density compared to that of the surrounding fluid, the results for all groups are in good agreement up to the point of break up, after which all three codes predict different bubble shapes. This highlights the need for the research community to invest more effort in obtaining reference solutions to problems involving break up and coalescence.\ud Other research groups are encouraged to participate in these benchmarks by contacting the authors and submitting their own data. The reference data for the computed benchmark quantities can also be supplied for validation purposes

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Algebraic Flux Correction I. Scalar Conservation Laws

Kuzmin

Möller

105

273

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This chapter is concerned with the design of high-resolution finite element schemes satisfying the discrete maximum principle. The presented algebraic flux correction paradigm is a generalization of the flux-corrected transport (FCT) methodology. Given the standard Galerkin discretization of a scalar transport equation, we decompose the antidiffusive part of the discrete operator into numerical fluxes and limit these fluxes in a conservative way. The purpose of this manipulation is to make the antidiffusive term local extremum diminishing. The available limiting techniques include a family of implicit FCT schemes and a new linearity-preserving limiter which provides a unified treatment of stationary and time-dependent problems. The use of Anderson acceleration makes it possible to design a simple and efficient quasi-Newton solver for the constrained Galerkin scheme. We also present a linearized FCT method for computations with small time steps. The numerical behavior of the proposed algorithms is illustrated by a grid convergence study for convection-dominated transport problems and anisotropic diffusion equations.

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Flux Correction Tools for Finite Elements

Kuzmin

Turek

2002

Journal of Computational Physics

171

229

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Hierarchical slope limiting in explicit and implicit discontinuous Galerkin methods

Kuzmin

2014

Journal of Computational Physics

172

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Explicit and implicit FEM-FCT algorithms with flux linearization

Kuzmin

2009

Journal of Computational Physics

118

167

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Dmitri Kuzmin

Quantitative benchmark computations of two‐dimensional bubble dynamics

Algebraic Flux Correction I. Scalar Conservation Laws

Flux Correction Tools for Finite Elements

Hierarchical slope limiting in explicit and implicit discontinuous Galerkin methods

Explicit and implicit FEM-FCT algorithms with flux linearization

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