Self-interacting dark matter with observable N eff

Abstract

We propose a GeV-scale self-interacting dark matter (SIDM) candidate within a dark U(1)D gauged extension of the Standard Model (SM), addressing small-scale structure issues in while predicting an observable contribution to N eff in the form of dark radiation. The model introduces a fermionic DM candidate and a scalar φ, both charged under an unbroken U(1)D gauge symmetry. The self-interactions of are mediated by a light vector boson Xμ, whose mass is generated via the Stueckelberg mechanism. The relic abundance of is determined by thermal freeze-out through annihilations into Xμ, supplemented by a non-thermal component from the late decay of φ. Crucially, φ decays after the Big Bang Nucleosynthesis (BBN) but before the Cosmic Microwave Background (CMB) epoch, producing additional and a dark radiation species (S). This late-time production compensates for thermal underabundance due to efficient annihilation into light mediators, while remaining consistent with structure formation constraints. The accompanying dark radiation yields a detectable N eff, compatible with Planck 2018 bounds and within reach of next-generation experiments such as SPT-3G, CMB-S4, and CMB-HD.

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