Beyond the UVLF: High-redshift galaxy clustering with Roman
Program ID 19031
Science Category Galaxies
Program Type Analysis
Category Medium
Principal Investigator Julian Munoz
PI Institution University of Texas, Austin
Co-Investigators
  • Michael Boylan-Kolchin (University of Texas, Austin)
  • Steven Finkelstein (University of Texas, Austin)
  • Guochao Sun (Northwestern University)
Abstract The formation of the first galaxies is one of the major open questions in astrophysics. Current observations of UV luminosity functions suffer from intrinsic degeneracies, as very different galaxy-formation models can produce identical number counts. Galaxy clustering can break them by linking observed galaxies to their dark-matter host halos, and Roman uniquely combines the depth, area, and filter coverage to precisely measure clustering at z > 6, beyond the reach of current facilities. While Roman will revolutionize high-z clustering measurements, careful modeling will be required to understand them. We propose a theory program to interpret Roman’s measurements of galaxy clustering at high redshifts with three goals: (i) model galaxy bias at z > 9 to determine whether the JWST excess of UV-bright galaxies is due to enhanced star-formation efficiency or enhanced burstiness; (ii) map how the UV stochasticity depends on both halo mass and redshift across z = 6−11, distinguishing between competing feedback models; (iii) model the full two-point correlation function beyond the bias, constraining satellite fractions and the halo occupation distribution at high z for the first time. We will deliver a fully public pipeline to predict UVLFs and clustering jointly, validated against state-of-the-art simulations and applied to Roman HLWAS-Deep and Medium data. This program will maximize Roman’s returns by providing a publicly available theoretical pipeline needed to understand its clustering measurements. New data requires new tools, which this proposal will provide.