Photometric Estimates of Stellar Masses in High-Redshift Galaxies

Abstract

We present a new tool for the photometric estimate of stellar masses in distant galaxies. The observed SEDs are fitted by combining single stellar populations, with different SFRs and amounts of dust extinction. This approach gives us the best flexibility when dealing with the widest variety of physical situation for the target galaxies. In particular we tested the code on three classes of sources: dusty ISO-selected starbursts, K-band selected ellipticals/S0s and z=2-3 Lyman-break galaxies. We pay particular attention in evaluating the uncertainties in the stellar mass estimate, due to degeneracies in the physical parameters, different SFHs or metallicities. Based on optical-NIR photometric data, the stellar masses are found to have overall uncertainties of a factor of ~2 for E/S0s, ~2-5 for the starbursts population, and up to 10 for Ly-break galaxies. In any case the latter appear to correspond to a galaxy population significantly less massive than those observed at lower redshifts, possibly indicating substantial stellar build-up at z~1-2 in the field galaxy population. Using simulated deep SIRTF/IRAC observations of starbursts and Lyman-break galaxies, we investigate how an extension of the wavelength dynamic range will decrease the uncertainties in the stellar mass estimate, and find that they will reduce for both classes to factors of 2-3, good enough for statistically reliable determinations of the galaxy evolutionary mass functions.