We investigate the evolution of the phase-space distribution function around slightly perturbed stationary states and the process of violent relaxation in the context of the dissipationless collapse of an isolated spherical self-gravitating system. By means of the recently introduced symplectic coarse graining technique, we obtain an effective evolution equation that allows us to compute the scaling of the frequencies around a stationary state, as well as the damping times of Fourier modes of the distribution function, with the magnitude of the Fourier k -vectors themselves. We compare our analytical results with N-body simulations.
Symplectic coarse graining approach to the dynamics of spherical self-gravitating systems
Di Cintio Pierfrancesco;
2022
Abstract
We investigate the evolution of the phase-space distribution function around slightly perturbed stationary states and the process of violent relaxation in the context of the dissipationless collapse of an isolated spherical self-gravitating system. By means of the recently introduced symplectic coarse graining technique, we obtain an effective evolution equation that allows us to compute the scaling of the frequencies around a stationary state, as well as the damping times of Fourier modes of the distribution function, with the magnitude of the Fourier k -vectors themselves. We compare our analytical results with N-body simulations.| File | Dimensione | Formato | |
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2112.10709.pdf
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Descrizione: Symplectic coarse graining approach to the dynamics of spherical self-gravitating systems
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