The Rapidly Spinning Intermediate-Mass Black Hole 3XMM J150052.0+015452

TL;DR

This study analyzes the X-ray spectra of the tidal disruption event 3XMM J150052.0+015452, revealing it hosts a rapidly spinning intermediate-mass black hole with a mass around 2×10^5 solar masses and a near-extremal spin.

Contribution

The paper provides the first detailed spectral analysis confirming the black hole's mass and high spin, and explores the evolution of the corona during different accretion states.

Findings

Black hole mass estimated at ~2×10^5 solar masses.

Black hole spin is near extremal, >0.97.

Coronal properties vary with accretion rate, being optically thick and warm during super-Eddington phases.

Abstract

A star tidally disrupted by a black hole can form an accretion disc with a super-Eddington mass accretion rate; the X-ray emission produced by the inner disc provides constraints on the black hole mass $M_\bullet$ and dimensionless spin parameter $a_\bullet$. Previous studies have suggested that the $M_\bullet$ responsible for the tidal disruption event 3XMM J150052.0+015452 (hereafter J150052) is $\sim$10$^{5} M_{\odot}$, in the intermediate black hole (IMBH) regime. Fitting multi-epoch XMM-Newton and Chandra X-ray spectra obtained after 2008 during the source's decade-long decay, with our latest slim accretion disc model gives $M_\bullet = 2.0^{+1.0}_{-0.3}\times10^{5} M_{\odot}$ (at 68% confidence) and $a_\bullet > 0.97$ (a 84.1% confidence lower limit). The spectra obtained between 2008-2014 are significantly harder than those after 2014, an evolution that can be well explained by including the effects of inverse-Comptonisation by a corona on the early-time spectra. The corona is present when the source accretion rate is super-Eddington, while there is no evidence for its effect in data obtained after 2014, when the mass accretion rate is around the Eddington-limit. Based on our spectral study, we infer that the corona is optically thick and warm ($kT_e=2.3^{+2.7}_{-0.8}$ keV). Our mass and spin measurements of J150052 confirm it as an IMBH and point to a rapid, near extremal, spin. These $M_\bullet$ and $a_\bullet$ values rule out both vector bosons and axions of masses $\sim10^{-16}$ eV.