Born in the Dark: The Catastrophic Collapse of Fuzzy Dark Matter Solitons as the Origin of Little Red Dots

Abstract

JWST surveys have uncovered a population of compact, red sources ("Little Red Dots," LRDs) at z 5 that exhibit broad Balmer emission yet remain X-ray faint, implying heavy obscuration with NH 1024 cm-2. We propose that LRDs may trace a short-lived, obscured phase associated with rapid baryonic inflow inside the deep solitonic cores of fuzzy dark matter (FDM) halos. Combining the soliton size scaling with (i) the observed compact radii (re 30-100 pc) and (ii) the requirement that Compton-thick columns be achievable within a region of order the core radius, we find that particle masses m few × 10-22 eV are plausible for soliton masses Ms 108 - 109 M; we adopt m22=2 as a fiducial choice. A conservative mass-budget estimate for the obscuring column, together with isothermal hydrostatic stratification, indicates that configurations reaching NH 1024 - 1025 cm-2 require densities for which radiative losses (cooling and/or diffusion) occur faster than the dynamical time, suggesting that a long-lived static hot atmosphere is unlikely (an "Opacity Crisis") and that rapid inflow or radiation-pressure-driven evolution is favored. Using 5123 pseudo-spectral Schrödinger-Poisson simulations of idealized soliton mergers, we illustrate that compact, high-density soliton cores can form via violent relaxation under representative scalings. We discuss observational implications and tests, and outline the need for future radiation-hydrodynamic modeling to predict demographics and detailed spectra.