H-alpha emission in local galaxies: star formation, time variability and the diffuse ionized gas

TL;DR

This study uses detailed radiative transfer simulations of local galaxy models to analyze H-alpha emission, revealing its morphology, variability, and connection to star formation, with implications for high-redshift galaxy observations.

Contribution

It provides a comprehensive radiative transfer framework for understanding H-alpha emission in galaxies, including effects of dust, scattering, and ionizing photon absorption, advancing interpretation of star formation indicators.

Findings

H-alpha and H-beta profiles match observations of nearby galaxies.

Scattering increases H-alpha luminosity by approximately 40%.

Dust correction via Balmer decrement recovers intrinsic emission within 25%.

Abstract

The nebular recombination line H$\alpha$ is widely used as a star-formation rate (SFR) indicator in the local and high-redshift Universe. We present a detailed H$\alpha$ radiative transfer study of high-resolution isolated Milky-Way and Large Magellanic Cloud simulations that include radiative transfer, non-equilibrium thermochemistry, and dust evolution. We focus on the spatial morphology and temporal variability of the H$\alpha$ emission, and its connection to the underlying gas and star formation properties. The H$\alpha$ and H$\beta$ radial and vertical surface brightness profiles are in excellent agreement with observations of nearby galaxies. We find that the fraction of H$\alpha$ emission from collisional excitation amounts to $f_{\rm col}\sim5-10\%$, only weakly dependent on radius and vertical height, and that scattering boosts the H$\alpha$ luminosity by $\sim40\%$. The dust correction via the Balmer decrement works well (intrinsic H$\alpha$ emission recoverable within $25\%$), though the dust attenuation law depends on the amount of attenuation itself both on spatially resolved and integrated scales. Important for the understanding of the H$\alpha$-SFR connection is the dust and helium absorption of ionizing radiation (Lyman continuum [LyC] photons), which are about $f_{\rm abs}\approx28\%$ and $f_{\rm He}\approx9\%$, respectively. Together with an escape fraction of $f_{\rm esc}\approx6\%$, this reduces the available budget for hydrogen line emission by nearly half ($f_{\rm H}\approx57\%$). We discuss the impact of the diffuse ionized gas, showing - among other things - that the extraplanar H$\alpha$ emission is powered by LyC photons escaping the disc. Future applications of this framework to cosmological (zoom-in) simulations will assist in the interpretation of spectroscopy of high-redshift galaxies with the upcoming James Webb Space Telescope.