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Relaxation of collisionless systems

Violent Relaxation J.A. de Freitas Pacheco Université de Nice-Sophia Antipolis Observatoire de la Côte d’Azur ( UFES – 2013). Relaxation of collisionless systems.

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Relaxation of collisionless systems

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  1. Violent RelaxationJ.A. de Freitas PachecoUniversité de Nice-Sophia AntipolisObservatoire de la Côte d’Azur(UFES – 2013)

  2. Relaxation of collisionless systems • Nearly universal brightness profile of E-galaxies requires short timescale processes and no dependence on the stellar mass, otherwise significant color gradients would be observed. • Simulations indicate that dark matter halos have peaked profiles (Navarro-Frenk-White -1995) – Are these “universal” ? • Two-body collisions have an extremely high relaxation timescale (greater than the Hubble scale). • Hénon (1964) – studied numerically relaxation of N-body systems in the presence of a variable potential • Violent relaxation (Lynden-Bell, 1967) describes how a collisionless dynamical system relaxes from a chaotic initial state to quasi equilibrium, when rapid changes in the gravitational potential occur during the gravitational collapse or following a merger episode

  3. Color profiles of Elliptical Galaxies Idiart, Michard & de Freitas Pacheco (A&A 383, 30, 2002)

  4. Relaxation & Density Profiles of Halos • Central slopes (dlg/dlgr) may depend on the merger history (Klypin et al. 2001) or on the initial conditions (Ascasibar et al. 2004) • Simulations (Henriksen 2004) indicate that dynamical young systems (clusters of galaxies) have ’’cusped’’ profiles; dwarf galaxies have ’’cored’’ ones • Relaxation seems to be consequence of collective effects re-excited by successive merger events (Ricotti 2003) • Central cusps could be the consequence of the inflow of low-entropy material ( s  -log Q) • High resolution simulations indicate Q  r -, where the exponent is the same either for galaxy-size halos (Taylor & Navarro 2001) or cluster-size halos (Rasia et al. 2003), namely,   1.87 • Hierarchical assembly of dark matter halos preserves phase-space stratification or Q r - represents a generic feature of violent relaxation (Williams et al. 2004)?

  5. Violent Relaxation - criticisms *Numerical experiments indicate that N-body systems do not reach a Lynden-Bell distribution. * Simulations of the gravitational collapse suggest that violent relaxation enhances segregation in the energy space (Funato et al. 1992). * Simulations with N-body tree code (Merrall & Henriksen 2003) Indicate that relaxed systems have a Gaussian distribution. * Numerical studies of the relaxation process by Diemand et al. (2004) Confirm that the resulting velocity distribution is Gaussian but with negative kurtosis  flat topped profile. Merrall & Hendriksen 2003 Diemand et al. 2004

  6. Simulations(Peirani, Durier & de Freitas Pacheco MNRAS 367, 1011, 2006) • Code parallel adaptive – HYDRA – (Couchman et al. 1985) • Cosmology  CDM ( h = 0.65 ; m = 0.3 ; V = 0.7 ; 8 = 0.9) • Volume  cube side = 30h-1 Mpc • Follow-up  60  z = 0 • Mass resolution = 2.05 x 108 M Halo identification technique

  7. Global Evolution of Q=/3 density calculated by Voronoi tessellation inside r* = 0.1GM2 / |W| Q  -2.1 for both CDM and WDM Halos evolved only by accretion have slightly higher Q values for a given velocity dispersion

  8. Core & phase-space densities

  9. Central Phase-Space Density • *Dark matter density overestimated in central regions of dwarf and LBS galaxies ? • * Clusters have lower phase-density than dwarfs – they suffered a series of mergers able to reduce Q. • (if the phase-space density decreases in mergers because of violent relaxation – Tremaine, Hénon & Lynden-Bell 1986) • *Flattening of the central cusp implies that clusters should be dynamically younger ! • *Is the diagram Q vs an evolutionary path ?

  10. Best fit  Q M-0.83 z = 0 Phase-space density indicator Q as a function of the halo mass at z = 0. Halos which have grown mainly by mergers have slightly lower values of the phase-space density.

  11. Mass evolution Virial ratio 2E/|W| Potential Energy Kinetic Energy

  12. Examples of Individual Evolution phase-space density dispersion velocity central density

  13. Effects of Mergers dQ/dt evolution d/dt evolution

  14. Simulations - main results • The core density of halos decreases on the average by one order of magnitude in the interval 10 < z < 0 • A rapid increase of the velocity dispersion associated to the relaxation process (energy transfer from bulk-to-random motions) occurs in the redshift interval 10 < z < 6.5, followed by a late period of “slow heating” • Merger episodes show an energy transfer from bulk-to-random motions due to collective effects, heating all particles regardless their initial energies • Halos issued from simulations with particles of different masses relax as predictions of “violent relaxation”, i.e., all particles have the very same velocity dispersion. • The phase-space density indicator Q decreases on the average by a factor of 40 in the first 0.5 Gyr and then by a factor of 20 during the late evolution.

  15. Phase-space density at shell crossing • Non-linear effects are difficult to be analyzed by analytical methods • Press-Schechter approach – spherical symmetric overdense region of radius R(t) evolves as a closed universe • As long as expansion is matter dominated, the external radius R(t) enclosing a mass M obeys the equation • Integration constant E related to the “curvature” of a “closed” world-model

  16. Parametric solution  Maximum expansion at  =  and collapse at  = 2 with Evolution a) in the early phases, the perturbation expands as fast as the background but the contrast increases b) at maximum radius (zero kinetic energy) the perturbation “detaches” the background and begins to collapse c) in this situation, the potential energy is comparable to the kinetic energy and the system expands, contracts, relaxes until the virial relation is satisfied d)in the relaxation process, bulk motion is transferred to random motions via an important phase mixing mechanism

  17. At maximum expansion (dR/dt = 0)  After “bounce”, since energy is conserved  Using the virial : and combining these relations  At maximum expansion  Using the background relation (Einstein-de Sitter)  Their ratio  and similarly, for the contrast after collapse

  18. The expected density contrast at virialization Mean halo density at virialization: Since 32 = -2E , the 1D velocity dispersion where using the fit from simulations  it results for the phase-space density See details in arXiv:0701292 Virialization redshift for a halo of mass M Spherical model Phase-space density at virialization

  19. Phase-space mixing

  20. Phase Mixing Diffusion of nearby points in the phase-space due to differences in orbital periods This process is, in general, reversible (the system keeps the knowledge of the initial conditions Chaotic mixing The system loses information about initial conditions (irreversible process). Diffusion of nearby points in the phase-space is due the chaotic nature of the orbits The diffusion time scale is defined by the Lyapunov exponents. For a collisionless system, the sum of all Lyapunov exponents is equal to zero Li axes of an ellipsoid (2N dimensions) in phase-space with a mean radius r Regular orbits i = 0 Chaotic orbits – divergence of orbits  exp(t)

  21. Phase-space evolution of particles in a harmonic potential well (Dehnen 2005) Mixing is due to non-local large scale dynamics, occurring far from equilibrium but promoting equilibrium

  22. Phase-space mixing in mergers Example of two sub-halos captured in eccentric orbits and disrupted by tidal forces. Satellites transfer angular momentum to the main halo. Main-halo  M = 4.0x1012 M1D = 202 km/s sub-halo-1  M = 1.6x1011 M1D = 51 km/s Po ~ 6 Gyr a ~ 100 kpc sub-halo-2  2.8x1011 M1D = 78 km/s Po ~ 2 Gyr

  23. After merging, the velocity distribution of structures are “flat-topped” Gaussians Main halo has a kurtosis k =[<v4>/<v2>2]-3 = -0.57 while subhalo-2 has k = -0.73

  24. Subhalo-1 preserves identity and develops high velocity tails. Subhalo2 mixes completely in a timescale of ~ 3.4 Gyr

  25. Top – evolution of the virial ratio (whole system). A maximum occurs at each periastron passage. Right – structures in phase-space appear in each periastron passage Main halo – kurtosis = -0.64 Subhalo – k = -0.85 Halo – M =3.3x1012 Msubhalo – 5.2x1011 M

  26. Totally disrupted subhalo of mass 1.2x1012 M comparable to that of the main halo 4.3x1013 M At z = 0 the captured halo is completely mixed in phase-space. Mixing occurs mainly at periastron and are probably driven by compressive tidal shocks Again, the main halo has a negative kurtosis = -0.57 and the subhalo k = -0.65

  27. Summary • The relaxation of collisionless systems is not fully understood at present time • Possible issues – relaxation via collective effects and/or in the presence of rapid changes of the gravitational potential (“violent relaxation”) • VR can be seen as a transfer of kinetic energy from bulk to random motions • VR predicts the same velocity dispersion for particles of different masses constituting the system – numerical experiments confirm such a prediction • Different numerical experiments indicate that systems relaxed via gravitational collapse and/or mergers have velocity distributions described by Gaussians with negative kurtosis (“flat-topped” profiles) – confirmed by cosmological simulations. • The phase-space density indicator Q decreases by several orders of magnitude during the relaxation process. Predictions based on the “spherical model” are in agreement with results of cosmological simulations.

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