High-mass X-ray binaries in nearby metal-poor galaxies: on the contribution to nebular HeII emission

TL;DR

This study investigates whether high-mass X-ray binaries (HMXBs) significantly contribute to nebular HeII emission in metal-poor galaxies, finding they are insufficient and suggesting alternative sources or mechanisms.

Contribution

The paper provides the first comprehensive test showing HMXBs cannot account for observed HeII emission in low-metallicity galaxies, challenging previous assumptions.

Findings

HMXBs are inefficient at producing HeII-ionizing photons.

Observed X-ray luminosities in sample galaxies are too low to power HeII emission.

Alternative explanations like stellar winds or hot binary products are proposed.

Abstract

Despite significant progress both observationally and theoretically, the origin of high-ionization nebular HeII emission in galaxies dominated by stellar photoionization remains unclear. Accretion-powered radiation from high-mass X-ray binaries (HMXBs) is still one of the leading proposed explanations for the missing $\mathrm{He^+}$-ionizing photons, but this scenario has yet to be conclusively tested. In this paper, we present nebular line predictions from a grid of photoionization models with input SEDs containing the joint contribution of both stellar atmospheres and a multi-color disk model for HMXBs. This grid demonstrates that HMXBs are inefficient producers of the photons necessary to power HeII, and can only boost this line substantially in galaxies with HMXB populations large enough to power X-ray luminosities of $10^{42}$ erg/s per unit star formation rate (SFR). To test this, we assemble a sample of eleven low-redshift star-forming galaxies with high-quality constraints on both X-ray emission from Chandra and HeII emission from deep optical spectra, including new observations with the MMT. These data reveal that the HMXB populations of these nearby systems are insufficient to account for the observed HeII strengths, with typical X-ray luminosities or upper limits thereon of only $10^{40}$-$10^{41}$ erg/s per SFR. This indicates that HMXBs are not the dominant source of $\mathrm{He^+}$ ionization in these metal-poor star-forming galaxies. We suggest that the solution may instead reside in revisions to stellar wind predictions, softer X-ray sources, or very hot products of binary evolution at low metallicity.