Dark matter isocurvature from curvature

Holst, Ian; Hu, Wayne; Jenks, Leah

doi:10.1103/physrevd.109.063507

Title: Dark matter isocurvature from curvature

Journal Article · 05 March 2024 · Physical Review. D.

DOI: https://doi.org/10.1103/physrevd.109.063507 · OSTI ID:2481454

^[1]; Hu, Wayne ^[1]; Jenks, Leah ^[1]

University of Chicago, IL (United States)

Isocurvature fluctuations, where the relative number density of particle species spatially varies, can be generated from initially adiabatic, or curvature, fluctuations if the various species fall out of or were never in thermal equilibrium. The freezing of the thermal relic dark matter abundance is one such case, but for modes that are still outside the horizon the amplitude is highly suppressed and originates from the small change in the local expansion rate due to the local space curvature produced by the curvature fluctuation. We establish a simple separate-universe method for calculating this generation that applies to both freeze-in and freeze-out models, identify three critical epochs for this process, and give general scaling behaviors for the amplitude in each case: the freezing epoch, the kinetic decoupling epoch and matter-radiation equality. Freeze-out models are typically dominated by spatially modulated annihilation from the latter epochs and can generate much larger isocurvature fluctuations compared with typical freeze-in models, albeit still very small and observationally allowed by cosmic microwave background measurements. Here, we illustrate these results with concrete models where the dark matter interactions are vector or scalar mediated.

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Research Organization:: University of Chicago, IL (United States)

Sponsoring Organization:: USDOE

Grant/Contract Number:: SC0009924

OSTI ID:: 2481454

Journal Information:: Physical Review. D., Journal Name: Physical Review. D. Journal Issue: 6 Vol. 109; ISSN 2470-0010

Publisher:: American Physical Society (APS)Copyright Statement

Country of Publication:: United States

Language:: English

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79 ASTRONOMY AND ASTROPHYSICS
Cosmic microwave background
Cosmology
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