Overmassive black holes in the early Universe can be explained by gas-rich, dark matter-dominated galaxies

Abstract

JWST has revealed the apparent evolution of the black hole (BH)-stellar mass (MBH-M) relation in the early Universe, while remaining consistent with the BH-dynamical mass (MBH-Mdyn) relation. We predict BH masses for z>3 galaxies in the high-resolution THESAN-ZOOM simulations by assuming the MBH-Mdyn relation is fundamental. Even without live BH modelling, our approach reproduces the JWST-observed MBH distribution, including overmassive BHs relative to the local MBH-M relation. We find that MBH/M declines with M, evolving from 0.1 at M=106\,M to 0.01 at M=1010.5\,M. This trend reflects the dark matter (fDM) and gas fractions (fgas), which decrease with M but show little redshift evolution down to z=3, resulting in small M/Mdyn ratios and thus overmassive BHs in low-mass galaxies. We use Prospector-derived stellar masses and star-formation rates to infer fgas across 48,022 galaxies in JADES at 3<z<9, finding excellent agreement with our simulation. Our results demonstrate that overmassive BHs would naturally result from a fundamental MBH-Mdyn relation and be typical of the gas-rich, dark matter-dominated nature of low-mass, high-redshift galaxies. Such overmassive BHs may strongly influence early galaxy formation, and we caution that our approach does not include the self-consistent BH-galaxy co-evolution required for a complete understanding.