Portal de Periódicos da CAPES

The MUSE Hubble Ultra Deep Field Survey

2018; EDP Sciences; Volume: 619; Linguagem: Inglês

10.1051/0004-6361/201833136

1432-0746

Leindert Boogaard, J. Brinchmann, Nicolas Bouché, Mieke Paalvast, Roland Bacon, R. J. Bouwens, T. Contini, M. L. P. Gunawardhana, Hanae Inami, R. A. Marino, Michael V. Maseda, Peter Mitchell, Themiya Nanayakkara, Johan Richard, Joop Schaye, C. Schreiber, Sandro Tacchella, L. Wisotzki, Johannes Zabl,

Stellar, planetary, and galactic studies

Star-forming galaxies have been found to follow a relatively tight relation between stellar mass ($M_{*}$) and star formation rate (SFR), dubbed the `star formation sequence'. A turnover in the sequence has been observed, where galaxies with $M_{*} < 10^{10} {\rm M}_{\odot}$ follow a steeper relation than their higher mass counterparts, suggesting that the low-mass slope is (nearly) linear. In this paper, we characterise the properties of the low-mass end of the star formation sequence between $7 \leq \log M_{*}[{\rm M}_{\odot}] \leq 10.5$ at redshift $0.11 < z < 0.91$. We use the deepest MUSE observations of the Hubble Ultra Deep Field and the Hubble Deep Field South to construct a sample of 179 star-forming galaxies with high signal-to-noise emission lines. Dust-corrected SFRs are determined from H$β$ $λ4861$ and H$α$ $λ6563$. We model the star formation sequence with a Gaussian distribution around a hyperplane between $\log M_{*}$, $\log {\rm SFR}$, and $\log (1+z)$, to simultaneously constrain the slope, redshift evolution, and intrinsic scatter. We find a sub-linear slope for the low-mass regime where $\log {\rm SFR}[{\rm M}_{\odot}/{\rm yr}] = 0.83^{+0.07}_{-0.06} \log M_{*}[{\rm M}_{\odot}] + 1.74^{+0.66}_{-0.68} \log (1+z)$, increasing with redshift. We recover an intrinsic scatter in the relation of $σ_{\rm intr} = 0.44^{+0.05}_{-0.04}$ dex, larger than typically found at higher masses. As both hydrodynamical simulations and (semi-)analytical models typically favour a steeper slope in the low-mass regime, our results provide new constraints on the feedback processes which operate preferentially in low-mass halos.