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Autores principales: Parshikov, A. N., Medin, S. A., Rublev, G. D., Dyachkov, S. A.
Formato: Preprint
Publicado: 2023
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Acceso en línea:https://arxiv.org/abs/2306.08444
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author Parshikov, A. N.
Medin, S. A.
Rublev, G. D.
Dyachkov, S. A.
author_facet Parshikov, A. N.
Medin, S. A.
Rublev, G. D.
Dyachkov, S. A.
contents The paper proposes a way to control the viscosity of numerical approximation in the contact SPH method. This variant of SPH contains momentum and energy fluxes in the right-hand sides of the equations, which are calculated using the solution of the Riemann problem between each pair of neighboring particles within the smoothing kernel support radius, which is similar to the procedure for calculating fluxes across cell boundaries in Godunov schemes. Such SPH method does not require the use of artificial viscosity, because the significant numerical viscosity is already introduced by a Riemann problem solution. The magnitude of numerical viscosity decreases linearly with particle size, however, it becomes comparable with the physical viscosity for most materials when the particle size is about $\thicksim 1\,$nm, which hampers the correct accounting for viscous effects in real-life problems. In this study we develop a method for reducing the viscous stresses of numerical origin, for which a correcting viscous stress tensor is constructed on the basis of the analytical solution for discontinuous viscous flow. The use of such correction makes it possible to improve the agreement with the experiment in the simulation of viscous flows.
format Preprint
id arxiv_https___arxiv_org_abs_2306_08444
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Adjusting the numerical viscosity in the Godunov-like SPH method at modeling compressible flows
Parshikov, A. N.
Medin, S. A.
Rublev, G. D.
Dyachkov, S. A.
Computational Physics
The paper proposes a way to control the viscosity of numerical approximation in the contact SPH method. This variant of SPH contains momentum and energy fluxes in the right-hand sides of the equations, which are calculated using the solution of the Riemann problem between each pair of neighboring particles within the smoothing kernel support radius, which is similar to the procedure for calculating fluxes across cell boundaries in Godunov schemes. Such SPH method does not require the use of artificial viscosity, because the significant numerical viscosity is already introduced by a Riemann problem solution. The magnitude of numerical viscosity decreases linearly with particle size, however, it becomes comparable with the physical viscosity for most materials when the particle size is about $\thicksim 1\,$nm, which hampers the correct accounting for viscous effects in real-life problems. In this study we develop a method for reducing the viscous stresses of numerical origin, for which a correcting viscous stress tensor is constructed on the basis of the analytical solution for discontinuous viscous flow. The use of such correction makes it possible to improve the agreement with the experiment in the simulation of viscous flows.
title Adjusting the numerical viscosity in the Godunov-like SPH method at modeling compressible flows
topic Computational Physics
url https://arxiv.org/abs/2306.08444