Black hole hyperaccretion in collapsars. II. Gravitational waves

TL;DR

This paper explores gravitational wave emissions from neutrino-dominated accretion flows in collapsars, suggesting potential detectability and implications for understanding gamma-ray burst central engines.

Contribution

It provides the first detailed analysis of GW signals from anisotropic neutrino emission in NDAFs within collapsar models, highlighting their detectability and astrophysical significance.

Findings

GW frequency ~ 1-100 Hz

GW strains slightly affected by progenitor properties

Detectable GWs at 10 kpc distance

Abstract

As progenitors of gamma-ray bursts (GRBs), core collapse of massive stars and coalescence of compact object binaries are believed to be powerful sources of gravitational waves (GWs). In the collapsar scenario, a rotating stellar-mass black hole (BH) surrounded by a hyperaccretion disk might be running in the center of a massive collapsar, which is one of the plausible central engines of long GRBs. Such a BH hyperaccretion disk would be in a state of a neutrino-dominated accretion flow (NDAF) at the initial stage of the accretion process; meanwhile, the jets attempt to break out from the envelope and circumstellar medium to power GRBs. In addition to collapsars, the BH hyperaccretion systems are important sources of neutrinos and GWs. In this paper, we investigated the GW emission generated by the anisotropic neutrino emission from NDAFs in the collapsar scenarios. As the results indicate, the typical frequency of GWs is $\sim$ 1-100 Hz, and the masses and metallicities of the progenitor stars have slight effects on the GW strains. The GWs from NDAFs might be detected by operational or planned detectors at the distance of 10 kpc. Moreover, comparisons of the detectable GWs from collapsars, NDAFs, and GRB jets (internal shocks) are displayed. By combining the electromagnetic counterparts, neutrinos, and GWs, one may constrain the characteristics of collapsars and central BH accretion systems.