# The Arrow of Time in the collapse of collisionless self-gravitating   systems: non-validity of the Vlasov-Poisson equation during violent   relaxation

**Authors:** Leandro Beraldo e Silva, Walter de Siqueira Pedra, Laerte Sodr\'e,, Eder Perico, Marcos Lima

arXiv: 1703.07363 · 2017-09-21

## TL;DR

This study demonstrates that the violent relaxation of collisionless self-gravitating systems involves entropy increase, indicating the Vlasov-Poisson equation's non-validity during this phase, and suggests alternative kinetic descriptions.

## Contribution

The paper provides evidence that violent relaxation cannot be accurately modeled by the Vlasov-Poisson equation, proposing the need for alternative kinetic equations based on N-body simulations.

## Key findings

- Entropy increases during violent relaxation, contradicting Vlasov-Poisson conservation.
- Long-term evolution aligns with the orbit-averaged Fokker-Planck model.
- Entropy evolution converges across different simulation codes and estimators.

## Abstract

The collapse of a collisionless self-gravitating system, with the fast achievement of a quasi-stationary state, is driven by violent relaxation, with a typical particle interacting with the time-changing collective potential. It is traditionally assumed that this evolution is governed by the Vlasov-Poisson equation, in which case entropy must be conserved. We run N-body simulations of isolated self-gravitating systems, using three simulation codes: NBODY-6 (direct summation without softening), NBODY-2 (direct summation with softening) and GADGET-2 (tree code with softening), for different numbers of particles and initial conditions. At each snapshot, we estimate the Shannon entropy of the distribution function with three different techniques: Kernel, Nearest Neighbor and EnBiD. For all simulation codes and estimators, the entropy evolution converges to the same limit as N increases. During violent relaxation, the entropy has a fast increase followed by damping oscillations, indicating that violent relaxation must be described by a kinetic equation other than the Vlasov-Poisson, even for N as large as that of astronomical structures. This indicates that violent relaxation cannot be described by a time-reversible equation, shedding some light on the so-called "fundamental paradox of stellar dynamics". The long-term evolution is well described by the orbit-averaged Fokker-Planck model, with Coulomb logarithm values in the expected range 10-12. By means of NBODY-2, we also study the dependence of the 2-body relaxation time-scale on the softening length. The approach presented in the current work can potentially provide a general method for testing any kinetic equation intended to describe the macroscopic evolution of N-body systems.

## Full text

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## Figures

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## References

89 references — full list in the complete paper: https://tomesphere.com/paper/1703.07363/full.md

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Source: https://tomesphere.com/paper/1703.07363