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Evaporating the Milky Way halo and its satellites with inelastic self-interacting dark matter

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arxiv 1805.03203 v2 pith:SRE7UEI2 submitted 2018-05-08 astro-ph.GA hep-ph

Evaporating the Milky Way halo and its satellites with inelastic self-interacting dark matter

classification astro-ph.GA hep-ph
keywords inelasticdarkmattercrosshaloself-interactingdensityelastic
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Self-interacting dark matter provides a promising alternative for the cold dark matter paradigm to solve potential small-scale galaxy formation problems. Nearly all self-interacting dark matter simulations so far have considered only elastic collisions. Here we present simulations of a galactic halo within a generic inelastic model using a novel numerical implementation in the Arepo code to study arbitrary multi-state inelastic dark matter scenarios. For this model we find that inelastic self-interactions can: (i) create larger subhalo density cores compared to elastic models for the same cross section normalisation; (ii) lower the abundance of satellites without the need for a power spectrum cutoff; (iii) reduce the total halo mass by about 10%; (iv) inject the energy equivalent of O(100) million Type II supernovae in galactic haloes through level de-excitation; (v) avoid the gravothermal catastrophe due to removal of particles from halo centers. We conclude that a ~5 times larger elastic cross section is required to achieve the same central density reduction as the inelastic model. This implies that well-established constraints on self-interacting cross sections have to be revised if inelastic collisions are the dominant mode. In this case significantly smaller cross sections can achieve the same core density reduction thereby increasing the parameter space of allowed models considerably.

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Cited by 3 Pith papers

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

  1. Self-interacting dark matter promotes bar formation in disk galaxies

    astro-ph.GA 2026-06 unverdicted novelty 6.0

    SIDM halos accelerate bar formation and growth in disk galaxies through enhanced angular momentum exchange, independent of core formation.

  2. Cosmology of Inelastic Self-Interacting Dark Matter: Linear Evolution and Observational Constraints

    astro-ph.CO 2026-04 unverdicted novelty 5.0

    Inelastic self-interacting dark matter with small mass splitting produces a cutoff in the matter power spectrum at k > 1 h Mpc^{-1} whose location depends on cross-section normalization, velocity dependence, dark matt...

  3. Bypassed Core Formation in Milky Way-Mass SIDM Halos: Implications for the Local Group Past-Pericenter Scenario

    astro-ph.GA 2026-04 unverdicted novelty 5.0

    MW-mass SIDM halos bypass core formation and enter immediate core collapse due to baryonic preconditioning, allowing the compact stellar disk and bulge to survive close pericenter passages while the diffuse halo is mo...