James Webb Space Telescope Feed Post

Building the First Galaxies -- Chapter 2. Starbursts Dominate The Star Formation Histories of 6 < z <12 Galaxies

Paper abstract: We use SEDz*, a code designed to chart star formation histories of 6 < z < 12 galaxies, to analyze the SEDs of 982 galaxies with deep JWST-NIRCam imaging in the GOODS-S field. We show how SEDz* assembles an SED to match observations, from component stellar-population templates, graphing the contribution of each by epoch to confirm the robustness of the technique. Very good SED fits for most SFHs demonstrates the compatibility of our templates with generations of stars in these first galaxies, even though they are derived from present-epoch stars in our Galaxy -- as expected, because the light is dominated by main-sequence A-stars, free of post-main-sequence complexity and insensitive to heavy-element compositions. We confirm earlier results in Dressler+2023: (1) Four types of star formation histories (SFHs) -- burst, stochastic, 3-epoch `contiguous,' and longer `continuous' -- cover the variety of histories: (2) Starbursts - both single and multiple -- play the lead role in this critical period of cosmic history, even though less common, longer SFHs (0.5-1.0 Gyr) produce comparable stellar mass. This buildup of stellar mass amounts to 10^8 to 10^9 Msun in an integer epoch, whether in a ~100 Myr burst or as part of a longer history. We suggest that the absence of rising SFHs could be explained by an intense dust-enshrouded phase lasting tens of Myr that precedes their dust-free SFHs. With comparable contributions to the stellar mass by the four different SFH types, the stellar mass of these ~1000 galaxies amounts to ~2 x10^12 Msun by z = 6. We find no strong dependencies of the different SFH types with the large-scale environment. However, the discovery of a compact group of 16 galaxies, 9 of which had first star formation at z=11-12, suggests that long SFHs are much more common in rare, dense environments, likely destined for the most populated places of the modern universe.