The infrared luminosity of retired and post-starburst galaxies: A cautionary tale for star formation rate measurements

Abstract

In galaxies with significant ongoing star formation there is an impressively tight correlation between total infrared luminosity (LTIR) and Hα luminosity (LHα), when Hα is properly corrected for stellar absorption and dust attenuation. This long-standing result gives confidence that both measurements provide accurate estimates of a galaxy's star formation rate (SFR), despite their differing origins. To test the extent to which this holds in galaxies with lower specific SFR (sSFR=SFR/Mgal), we combine optical spectroscopy from the SDSS with multi-wavelength (FUV to FIR) photometric observations from GAMA. We find that LTIR/LHα increases steadily with decreasing Hα equivalent width (WHα, a proxy for sSFR), indicating that both luminosities cannot provide a valid measurement of SFR in galaxies below the canonical star-forming sequence. For both `retired galaxies' and `post-starburst galaxies', LTIR/LHα can be up to a factor of 30 larger than for star-forming galaxies. The smooth change in LTIR/LHα, irrespective of star formation history, ionisation or heating source, dust temperature or other properties, suggests that the value of LTIR/LHα is determined by the balance between star-forming regions and ambient interstellar medium contributing to both LTIR and Hα. It is not a result of the differing timescales of star formation that these luminosities probe. While LHα can only be used to estimate the SFR for galaxies with WHα > 3A (sSFR 10-11.5/yr), we argue that the mid- and far-infrared can only be used to estimate the SFR of galaxies on the star-forming sequence with WHα >10A (sSFR 10-10.5/yr). We find no evidence for dust obscured star-formation in local post-starburst galaxies.