Stefan Adami scite author profile

The grid-aligned shock instability prevents an accurate computation of high Mach number flows using low-dissipation shock-capturing methods. In particular one manifestation, the so-called carbuncle phenomenon, has been investigated by various different groups over the past decades. Nevertheless, the mechanism of this instability is still not fully understood and commonly is suppressed by the introduction of additional numerical dissipation. However, present approaches may either significantly deteriorate the resolution of complex flow evolutions or involve additional procedures to limit stabilization measures to the shock region. Instead of increasing the numerical dissipation, in this paper, we present an alternative approach that relates the problem to the low Mach number in transverse direction of the shock front. We show that the inadequate scaling of the acoustic dissipation in the low Mach number limit is the prime reason for the instability. Our approach is to increase the "numerical" Mach

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Stefan Adami

A generalized wall boundary condition for smoothed particle hydrodynamics

A transport-velocity formulation for smoothed particle hydrodynamics

A new surface-tension formulation for multi-phase SPH using a reproducing divergence approximation

A conservative SPH method for surfactant dynamics

A low dissipation method to cure the grid-aligned shock instability

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