CEERS: Increasing Scatter along the Star-Forming Main Sequence Indicates Early Galaxies Form in Bursts

Abstract

We present the star-formation-rate -- stellar-mass (SFR-M) relation for galaxies in the CEERS survey at 4.5≤ z≤ 12. We model the \ and \ rest-UV and rest-optical photometry of galaxies with flexible star-formation histories (SFHs) using . We consider SFRs averaged from the SFHs over 10~Myr () and 100~Myr (), where the photometry probes SFRs on these timescales, effectively tracing nebular emission lines in the rest-optical (on 10~Myr timescales) and the UV/optical continuum (on 100 Myr timescales). We measure the slope, normalization and intrinsic scatter of the SFR-M relation, taking into account the uncertainty and the covariance of galaxy SFRs and M. From z 5-9 there is larger scatter in the -M relation, with σ( )=0.4~dex, compared to the -M relation, with σ( )=0.1~dex. This scatter increases with redshift and increasing stellar mass, at least out to z 7. These results can be explained if galaxies at higher redshift experience an increase in star-formation variability and form primarily in short, active periods, followed by a lull in star formation (i.e. ``napping'' phases). We see a significant trend in the ratio RSFR=(/) in which, on average, RSFR decreases with increasing stellar mass and increasing redshift. This yields a star-formation ``duty cycle'' of 40\% for galaxies with M/M≥ 9.3, at z5, declining to 20\% at z9. Galaxies also experience longer lulls in star formation at higher redshift and at higher stellar mass, such that galaxies transition from periods of higher SFR variability at z~6 to smoother SFR evolution at z~4.5.

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