Ignition of weak interactions and r-process outflows in super-collapsar accretion disks

Abstract

The collapse of rotating massive (~10 M) stars resulting in hyperaccreting black holes (BHs; "collapsars") is a leading model for the central engines of long-duration gamma-ray bursts (GRBs) and a promising source of rapid neutron capture ("r-process") elements. R-process nucleosynthesis in disk outflows requires the accretion flow to self-neutronize. This occurs because of Pauli-blocking at finite electron degeneracy, associated with a critical accretion rate M > M ign. We analytically examine the assumptions underlying this "ignition threshold" and its possible breakdown with increasing BH mass M. Employing three-dimensional general-relativistic magnetohydrodynamic simulations with weak interactions, we explore the physical conditions of collapsar accretion disks with M ~ 80-3000 M over more than a viscous timescale as they transition through the threshold. There is remarkable agreement between our simulations and the analytic result M ign α5/3M4/3 for M ~ 3-3000 M. Simulations and analytic analyses consistently show that the largest BHs leading to r-process nucleosynthesis at M ign are ≈ 3000 M, beyond which self-neutronization ceases, since the disk temperature T M-1/6 decreases below the neutron-proton mass difference (~MeV), suppressing the conversion of protons into neutrons. We show that stellar models of ~250-105M can give rise to BHs of M ~30-1000 M accreting at M M ign, yielding ~10-100 M of light and heavy r-process elements per event. These rare but prolific r-process sources in low-metallicity environments are associated with super-kilonovae and likely extremely energetic GRBs. Such signatures may be used to probe Population III stars.

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