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Dynamical Instability of Collapsed Dark Matter Halos

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arxiv 2108.11967 v2 pith:H2GEWHKT submitted 2021-08-26 astro-ph.CO astro-ph.GAastro-ph.HEgr-qchep-ph

Dynamical Instability of Collapsed Dark Matter Halos

classification astro-ph.CO astro-ph.GAastro-ph.HEgr-qchep-ph
keywords darkmatterblackcollapsecoreenergyinstabilitybinding
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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A self-interacting dark matter halo can experience gravothermal collapse, resulting in a central core with an ultrahigh density. It can further contract and collapse into a black hole, a mechanism proposed to explain the origin of supermassive black holes. We study dynamical instability of the core in general relativity. We use a truncated Maxwell-Boltzmann distribution to model the dark matter distribution and solve the Tolman-Oppenheimer-Volkoff equation. For given model parameters, we obtain a series of equilibrium configurations and examine their dynamical instability based on considerations of total energy, binding energy, fractional binding energy, and adiabatic index. Our numerical results indicate that the core can collapse into a black hole when the fractional binding energy reaches $0.035$ with a central gravitational redshift of $0.5$. We further show for the instability to occur in the classical regime, the boundary temperature of the core should be at least $10\%$ of the mass of dark matter particles; for a $10^9~{\rm M_\odot}$ seed black hole, the particle mass needs to be larger than a few keV. These results can be used to constrain different collapse models, in particular, those with dissipative dark matter interactions.

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Cited by 4 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Non-Equilibrium Relativistic Core Collapse of Self-Interacting Dark Matter Halos -- Limits On Seed Black Hole Mass

    astro-ph.CO 2026-01 unverdicted novelty 7.0

    Non-equilibrium relativistic SIDM halo collapse produces seed black holes of mass ~3e-8 of the halo mass at apparent horizon formation.

  2. SIDM and CDM interpretations of the million-solar-mass lensing perturber JVAS B1938+666-$\mathcal{V}$

    astro-ph.GA 2026-06 unverdicted novelty 5.0

    SIDM core-collapse simulations produce a dense central core matching the lensing perturber, while CDM requires an IMBH with extreme tidal mass loss whose realism is left open.

  3. Spherically Symmetric Fluid Simulations of Black Hole Accretion in Self-Interacting Dark Matter Halos

    astro-ph.CO 2026-07 unverdicted novelty 4.0

    1D hydrodynamic simulations find that SIDM heat transport competes with gravity to regulate black hole accretion, enabling rapid growth in SIS profiles up to 10,000 solar masses from a 100 solar mass seed in 2 Myr.

  4. Gravothermal Collapse: Robust Against Baryonic Feedback

    astro-ph.CO 2026-05 unverdicted novelty 4.0

    Baryonic feedback mildly delays but does not stall gravothermal collapse in high-concentration SIDM halos and allows resumption in median-concentration cases, yielding feedback-history-dependent central densities.