http://arxiv.org/abs/2201.12282
Numerical simulations demonstrate a link between dynamically cold initial solutions and self-similarity. However the nature of this link is not fully understood. Cold initial conditions alone without further symmetry do not lead to self-similarity. Here we show that when the system approaches equilibrium a new symmetry appears. The combination of this equilibrium symmetry with the cold symmetry in the initial conditions leads to full self-similarity. As a consequence for any initially cold system even if the initial spatial distribution is not self-similar we will observe an evolution towards self-similarity near equilibrium. The case of one dimensional systems or spherically symmetric systems in 3D are discussed in detail. Systems depending on the energy and other integrals are also considered. The problem of the degeneracy of the self-similar solutions at equilibrium is tackled. It is shown that very small perturbations at the center of the system have the ability to break this degeneracy and lead to the convergence towards a specific auto-similar solution.
C. Alard
Mon, 31 Jan 22
44/55
Comments: 9 pages, 3 figures
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