Dust Attenuation and H-alpha Star Formation Rates of z~0.5 Galaxies

TL;DR

This study uses deep imaging and spectroscopy to analyze dust attenuation and star formation rates in z~0.5 galaxies, demonstrating the reliability of SED-based SFR estimates and the importance of luminosity-dependent dust corrections.

Contribution

It introduces a comprehensive analysis of dust extinction and SFRs in z~0.5 galaxies, validating SED modeling as a reliable method for intrinsic SFR estimation without H-alpha measurements.

Findings

SED modeling accurately predicts H-alpha luminosities over 3 dex.

Luminosity-dependent dust correction aligns with observed data.

Stellar reddening is approximately half of nebular reddening.

Abstract

Using deep narrow-band and broad-band imaging, we identify 401 z~0.40 and 249 z~0.49 H-alpha line-emitting galaxies in the Subaru Deep Field. Compared to other H-alpha surveys at similar redshifts, our samples are unique since they probe lower H-alpha luminosities, are augmented with multi-wavelength (rest-frame 1000AA--1.5 microns) coverage, and a large fraction (20%) of our samples has already been spectroscopically confirmed. Our spectra allow us to measure the Balmer decrement for nearly 60 galaxies with H-beta detected above 5-sigma. The Balmer decrements indicate an average extinction of A(H-alpha)=0.7^{+1.4}_{-0.7} mag. We find that the Balmer decrement systematically increases with higher H-alpha luminosities and with larger stellar masses, in agreement with previous studies with sparser samples. We find that the SFRs estimated from modeling the spectral energy distribution (SED) is reliable---we derived an "intrinsic" H-alpha luminosity which is then reddened assuming the color excess from SED modeling. The SED-predicted H-alpha luminosity agrees with H-alpha narrow-band measurements over 3 dex (rms of 0.25 dex). We then use the SED SFRs to test different statistically-based dust corrections for H-alpha and find that adopting one magnitude of extinction is inappropriate: galaxies with lower luminosities are less reddened. We find that the luminosity-dependent dust correction of Hopkins et al. yields consistent results over 3 dex (rms of 0.3 dex). Our comparisons are only possible by assuming that stellar reddening is roughly half of nebular reddening. The strong correspondence argue that with SED modeling, we can derive reliable intrinsic SFRs even in the absence of H-alpha measurements at z~0.5.