Self-interacting Dark Scalar Spikes around Black Holes via Relativistic Bondi Accretion
Abstract
We consider the spike mass density profile in a dark halo by self-consistently solving the relativistic Bondi accretion of dark matter onto a non-spining black hole of mass M. We assume that the dominant component of the dark matter in the halo is a Standard model gauge-singlet scalar. Its mass m 10-5 eV and quartic self-coupling λ10-19 are constrained to be compatible with the properties of galactic dark halos. In the hydrodynamic limit, we find that the accretion rate is bounded from below, M min=96π G2M2 m4/λ3. Therefore, for M=106~ M we have M min1.41× 10-9~ M~ yr-1, which is subdominant compared to the Eddington accretion of baryons. The spike density profile 0(r) within the self-gravitating regime cannot be fitted well by a single-power law but a double-power one. Despite that, we can fit 0(r) piecewise and find that 0(r) r-1.20 near the sound horizon, 0(r) r-1.00 towards the Bondi radius and 0(r) r-1.08 for the region in between. This contrasts with more cuspy 0(r) r-1.75 for dark matter with Coulomb-like self-interaction.
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