3D-Herschel: Constraining Dust Emission with Panchromatic Modeling of 3D-HST Galaxies

Abstract

We present 3D-Herschel, a new publicly released 0.3-350μm photometric catalog that combines deblended Herschel far-infrared (FIR) imaging with the CANDELS/3D-HST legacy fields to probe the dust-obscured universe. Using the 17-parameter Bayesian fitting code Prospector-β, we model 41,387 galaxies spanning 0.5 < z < 2.5 to measure stellar and dust properties. Comparing fits with and without FIR constraints, we find that for the 3.2\% of galaxies with >3 σ detections in ≥2 Herschel bands, UV-MIR-only models (0.3-24μm) recover robust stellar ages, SFRs, and stellar masses (50-70\% within the median 1σ error). Consequently, the Prospector-β star-forming sequence is unchanged by the inclusion of FIR data (average deviation 0.10.07 dex between UV-MIR and UV-FIR fits at fixed stellar mass), confirming that the offset relative to UV+IR-based estimates reported by Leja et al. 2022 is robust to the lack of direct FIR constraints. However, the use of rigid log-average IR templates with fixed dust emission parameters (γ, Umin, qPAH) in UV-MIR modeling yields cold dust temperatures (7K colder than Herschel-informed fits at all redshifts) and an unevolving MIR-to-IR luminosity ratio, with 0.2 dex lower IR-to-7.7μm luminosity ratios at the low-mass end of Herschel-detected galaxies (log(M) 9.6 M). These results demonstrate that MIR-to-IR conversions depend on stellar mass, cautioning against LIR-independent templates without FIR data. For galaxies with <1011 \ M at z>1.5, Herschel can at best provide upper limits due to source confusion; next-generation FIR telescopes will be essential for distant galaxies.