A physically motivated `charge-exchange method' for measuring electron temperatures within HII regions

TL;DR

This paper introduces a new charge-exchange method to accurately measure electron temperatures in HII regions of nearby galaxies, improving understanding of abundance variations in the interstellar medium.

Contribution

The study develops and applies a novel charge-exchange technique to determine electron temperatures from strong emission lines in HII regions, validated against direct measurements.

Findings

Reproduces direct T_e measurements within ~600 K.

Identifies radial and azimuthal temperature variations in galaxy disks.

Increases statistical power of temperature measurements using optical IFU maps.

Abstract

Aims: Temperature uncertainties plague our understanding of abundance variations within the ISM. Using the PHANGS-MUSE large program, we develop and apply a new technique to model the strong emission lines arising from HII regions in 19 nearby spiral galaxies at ~50 pc resolution and infer electron temperatures for the nebulae. Methods: Due to the charge-exchange coupling of the ionization fraction of the atomic oxygen to that of hydrogen, the emissivity of the observed [OI]6300/Ha line ratio can be modeled as a function of gas phase oxygen abundance (O/H), ionization fraction (f_ion) and electron temperature (T_e). We measure (O/H) using a strong line metallicity calibration, and identify a correlation between f_ion and [SIII]9069/[SII]6716,6730, tracing ionization parameter variations. Results: We solve for T_e, and test the method by reproducing direct measurements of T_e([NII]5755) based on auroral line detections to within ~600 K. We apply this charge-exchange method of calculating T_e to 4,129 HII regions across 19 PHANGS-MUSE galaxies. We uncover radial temperature gradients, increased homogeneity on small scales, and azimuthal temperature variations in the disks that correspond to established abundance patterns. This new technique for measuring electron temperatures leverages the growing availability of optical integral field unit spectroscopic maps across galaxy samples, increasing the statistics available compared to direct auroral line detections.