Gauge-Independent Approach to Resonant Dark Matter Annihilation
Mateusz Duch, Bohdan Grzadkowski, Apostolos Pilaftsis

TL;DR
This paper develops a gauge-independent method for accurately calculating dark matter annihilation near resonances, addressing issues with traditional Breit-Wigner approaches and ensuring consistent high-energy behavior.
Contribution
It introduces a gauge-independent resummation framework using the Pinch Technique to improve dark matter annihilation predictions near resonances.
Findings
Predictions for dark matter abundance differ significantly from naive Breit-Wigner models.
The proposed method is gauge-fixing parameter independent.
Results are consistent with high-energy unitarity constraints.
Abstract
In spontaneously broken gauge theories, transition amplitudes describing dark-matter (DM) annihilation processes through a resonance may become highly inaccurate close to a production threshold, if a Breit-Wigner (BW) ansatz with a constant width is used. To partially overcome this problem, the BW propagator needs to be modified by including a momentum dependent decay width. However, such an approach to resonant transition amplitudes generically suffers from gauge artefacts that may also give rise to a bad or ambiguous high-energy behaviour for such amplitudes. We address the two problems of gauge dependence and high-energy unitarity within a gauge-independent framework of resummation implemented by the so-called Pinch Technique. We study DM annihilation via scalar resonances in a gauged U(1) complex-scalar extension of the Standard Model that features a massive stable gauge field…
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