SciPost Submission Page
Can WIMPs Survive a Magnetized Early Universe?
by Malcolm Fairbairn, María Olalla Olea-Romacho, Pranjal Ralegankar
Submission summary
| Authors (as registered SciPost users): | Maria Olalla Olea Romacho |
| Submission information | |
|---|---|
| Preprint Link: | scipost_202510_00046v1 (pdf) |
| Date accepted: | Nov. 11, 2025 |
| Date submitted: | Oct. 27, 2025, 4:03 p.m. |
| Submitted by: | Maria Olalla Olea Romacho |
| Submitted to: | SciPost Physics |
| Ontological classification | |
|---|---|
| Academic field: | Physics |
| Specialties: |
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| Approach: | Phenomenological |
Abstract
Primordial magnetic fields (PMFs) can seed additional small-scale matter fluctuations, leading to the formation of dense, early-collapsing dark matter structures known as minihalos. These minihalos may dramatically amplify the dark matter annihilation signal if dark matter is composed of self-annihilating thermal relic particles such as WIMPs. In this work, we explore the viability of this scenario by analysing the annihilation signal from minihalos with prompt central cusps, $\rho \propto r^{-3/2}$, formed due to the enhanced power spectrum induced by PMFs. Using observational constraints from the Virgo cluster and incorporating benchmark values for the magnetic field strength motivated by cosmological phase transitions such as the electroweak and QCD phase transitions, as well as the best-fit value from DESI and Planck data, we derive constraints on the dark matter annihilation cross section. We find that large portions of the WIMP parameter space are excluded, and magnetic fields produced during phase transitions with temperatures $T \lesssim 100 \, \rm{GeV}$ disfavour dark matter masses below $400 \, \rm{GeV}$. Notably, magnetic fields generated at or below the QCD phase transition scale, or with amplitudes favored by current cosmological data, are in strong tension with self-annihilating WIMPs across a wide mass range extending beyond the $\mathrm{TeV}$ scale. Our results establish indirect detection as a sensitive probe of the interplay between early-universe magnetogenesis and the microphysics of dark matter.
Author indications on fulfilling journal expectations
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- Present a breakthrough on a previously-identified and long-standing research stumbling block
Current status:
Editorial decision:
For Journal SciPost Physics: Publish
(status: Editorial decision fixed and (if required) accepted by authors)