The most extreme ultraluminous X-ray sources: evidence for intermediate-mass black holes?

TL;DR

This study investigates extremely luminous ultraluminous X-ray sources, providing evidence that some may host intermediate-mass black holes based on their X-ray properties and luminosities, advancing the understanding of black hole mass ranges.

Contribution

The paper presents a new sample of ultra-luminous X-ray sources with luminosities suggesting the presence of intermediate-mass black holes, supported by their spectral and variability characteristics.

Findings

Some sources are hyperluminous, with luminosities up to 3x10^41 erg/s.

X-ray spectra are harder and more variable than less luminous ULXs.

Properties are consistent with sub-Eddington hard state, implying IMBHs in the 10^3-10^4 M_Sun range.

Abstract

We present the results from an X-ray and optical study of a new sample of eight extreme luminosity ultraluminous X-ray source (ULX) candidates, which were selected as the brightest ULXs (with L_X > 5x10^40 erg/s) located within 100 Mpc identified in a cross correlation of the 2XMM-DR1 and RC3 catalogues. These objects are so luminous that they are difficult to describe with current models of super-Eddington accretion onto all but the most massive stellar remnants; hence they are amongst the most plausible candidates to host larger, intermediate-mass black holes (IMBHs). Two objects are luminous enough in at least one observation to be classed as hyperluminous X-ray source (HLX) candidates, including one persistent HLX in an S0 galaxy that (at 3x10^41 erg/s) is the second most luminous HLX yet detected. The remaining seven sources are located in spiral galaxies, and several appear to be closely associated with regions of star formation as is common for many less luminous ULXs. However, the X-ray characteristics of these extreme ULXs appear to diverge from the less luminous objects. They are typically harder, possessing absorbed power-law continuum spectra with photon indexes ~ 1.7, and are potentially more variable on short timescales, with data consistent with ~ 10-20 per cent rms variability on timescales of 0.2-2 ks. These properties appear consistent with the sub-Eddington hard state, which given the observed luminosities of these objects suggests the presence of IMBHs with masses in the range 10^3-10^4 M_Sun. As such, this strengthens the case for these brightest ULXs as good candidates for the eventual conclusive detection of the highly elusive IMBHs. However, we caution that a combination of the highest plausible super-Eddington accretion rates and the largest permitted stellar black hole remnants cannot be ruled out without future, improved observations.