Tracing the Mass-Dependent Star Formation History of Late-Type Galaxies using X-ray Emission: Results from the Chandra Deep Fields

We report on the X-ray evolution over the last ~9 Gyr of cosmic history (i.e., since z = 1.4) of late-type galaxy populations in the Chandra Deep Field-North and Extended Chandra Deep Field-South (CDF-N and E-CDF-S, respectively; jointly CDFs) survey fields. Our late-type galaxy sample consists of 2568 galaxies, which were identified using rest-frame optical colors and HST morphologies. We utilized X-ray stacking analyses to investigate the X-ray emission from these galaxies, emphasizing the contributions from normal galaxies that are not dominated by active galactic nuclei (AGNs). Over this redshift range, we find significant increases (factors of ~5--10) in the X-ray--to--optical mean luminosity ratio (L_X/L_B) and the X-ray--to--stellar-mass mean ratio (L_X/M*) for galaxy populations selected by L_B and M*, respectively. When analyzing galaxy samples selected via SFR, we find that the mean X-ray--to--SFR ratio (L_X/SFR) is consistent with being constant over the entire redshift range for galaxies with SFR = 1--100 Msol yr^-1, thus demonstrating that X-ray emission can be used as a robust indicator of star-formation activity out to z = 1.4. We find that the star-formation activity (as traced by X-ray luminosity) per unit stellar mass in a given redshift bin increases with decreasing stellar mass over the redshift range z = 0.2--1, which is consistent with previous studies of how star-formation activity depends on stellar mass. Finally, we extend our X-ray analyses to Lyman break galaxies at z ~ 3 and estimate that L_X/L_B at z ~ 3 is similar to its value at z = 1.4.