Reionization Topology as a Probe of Self-Interacting Dark Matter

Abstract

The topology of cosmic reionization, the sizes, shapes, and connectivity of ionized bubbles is a primary observable of next-generation 21\,cm experiments. We show that this topology is sensitive to the microphysics of dark matter. Self-interacting dark matter (SIDM), with cross-sections σ/m 1--10\;cm2/g motivated by small-scale structure anomalies, reduces halo gas binding energies and increases the duty cycle of ionizing-photon escape. At fixed global neutral fraction x HI, this reshapes the source population from rare, very bright emitters to more numerous, moderate emitters, producing qualitatively different ionization morphology. We decompose the effect into two scale-dependent levers: a 2--3\% emissivity-weighted bias shift at k 0.1\;h/Mpc, and a factor 2--4 shot-noise suppression at k 0.1--1\;h/Mpc. A halo-by-halo semi-numerical simulation at 1283 resolution confirms a 60--70\% increase in the Euler characteristic of the ionization field for σ/m 2\;cm2/g, detected at 3.8σ across ten independent realizations. A blowout model connecting the binding-energy reduction to the duty cycle through the ISM column density distribution yields a detection threshold at σ/m 1--2\;cm2/g. The signal exceeds the CDM baryonic uncertainty band and is robust to the functional form of the emissivity parametrization. The signal persists even if gravitational heating offsets 50--75\% of the blowout enhancement, and is not diluted by unresolved low-mass sources. Velocity-dependent SIDM produces a qualitatively distinct opposite-sign bias shift. These predictions are testable with SKA1-Low, establishing reionization as a new arena for probing dark matter models complementary to dwarf galaxies and galaxy clusters.