Coherent vortices in two-dimensional turbulence induce far-field effects that stabilize vorticity filaments and inhibit the generation of new vortices. We show that the large-scale energy sink often included in numerical simulations of statistically stationary two-dimensional turbulence reduces the stabilizing role of the vortices, leading to filament instability and to continuous formation of new coherent vortices. This counter-intuitive effect sheds new light on the mechanisms responsible for vortex formation in forced-dissipated two-dimensional turbulence and it has significant impact on the temporal evolution of the vortex population in freely-decaying turbulence. The time dependence of vortex statistics in the presence of a large-scale energy sink can be approximately described by a modified version of the scaling theory developed for small-scale dissipation.
Large-scale dissipation and filament instability in two-dimensional turbulence
A Provenzale
2005
Abstract
Coherent vortices in two-dimensional turbulence induce far-field effects that stabilize vorticity filaments and inhibit the generation of new vortices. We show that the large-scale energy sink often included in numerical simulations of statistically stationary two-dimensional turbulence reduces the stabilizing role of the vortices, leading to filament instability and to continuous formation of new coherent vortices. This counter-intuitive effect sheds new light on the mechanisms responsible for vortex formation in forced-dissipated two-dimensional turbulence and it has significant impact on the temporal evolution of the vortex population in freely-decaying turbulence. The time dependence of vortex statistics in the presence of a large-scale energy sink can be approximately described by a modified version of the scaling theory developed for small-scale dissipation.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
