Dark photon dark matter in the presence of inhomogeneous structure

Abstract Dark photon dark matter will resonantly convert into visible photons when the dark photon mass is equal to the plasma frequency of the ambient medium. In cosmological contexts, this transition leads to an extremely efficient, albeit short-lived, heating of the surrounding gas. Existing work...

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Main Authors: Samuel J. Witte, Salvador Rosauro-Alcaraz, Samuel D. McDermott, Vivian Poulin
Format: Article
Language:English
Published: SpringerOpen 2020-06-01
Series:Journal of High Energy Physics
Subjects:
Online Access:http://link.springer.com/article/10.1007/JHEP06(2020)132
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spelling doaj-0f457cd0f9db4f83bbe650918734e4e22020-11-25T03:55:06ZengSpringerOpenJournal of High Energy Physics1029-84792020-06-012020613510.1007/JHEP06(2020)132Dark photon dark matter in the presence of inhomogeneous structureSamuel J. Witte0Salvador Rosauro-Alcaraz1Samuel D. McDermott2Vivian Poulin3Instituto de Fisica Corpuscular (IFIC), CSIC-Universitat de ValenciaDepartamento de Física Téorica and Instituto de Física Téorica, IFT-UAM/CSIC, Universidad Autónoma de MadridTheoretical Astrophysics Group, Fermi National Accelerator LaboratoryLUPM, CNRS & Université de MontpellierAbstract Dark photon dark matter will resonantly convert into visible photons when the dark photon mass is equal to the plasma frequency of the ambient medium. In cosmological contexts, this transition leads to an extremely efficient, albeit short-lived, heating of the surrounding gas. Existing work in this field has been predominantly focused on understanding the implications of these resonant transitions in the limit that the plasma frequency of the Universe can be treated as being perfectly homogeneous, i.e. neglecting inhomogeneities in the electron number density. In this work we focus on the implications of heating from dark photon dark matter in the presence of inhomogeneous structure (which is particularly relevant for dark photons with masses in the range 10 −15 eV ≲ m A′ ≲ 10 −12 eV), emphasizing both the importance of inhomogeneous energy injection, as well as the sensitivity of cosmological observations to the inhomogeneities themselves. More specifically, we derive modified constraints on dark photon dark matter from the Ly-α forest, and show that the presence of inhomogeneities allows one to extend constraints to masses outside of the range that would be obtainable in the homogeneous limit, while only slightly relaxing their strength. We then project sensitivity for near-future cosmological surveys that are hoping to measure the 21cm transition in neutral hydrogen prior to reionization, and demonstrate that these experiments will be extremely useful in improving sensitivity to masses near ∼ 10 −14 eV, potentially by several orders of magnitude. Finally, we discuss implications for reionization, early star formation, and late-time y-type spectral distortions, and show that probes which are inherently sensitive to the inhomogeneous state of the Universe could resolve signatures unique to the light dark photon dark matter scenario, and thus offer a fantastic potential for a positive detection.http://link.springer.com/article/10.1007/JHEP06(2020)132Cosmology of Theories beyond the SMThermal Field Theory
collection DOAJ
language English
format Article
sources DOAJ
author Samuel J. Witte
Salvador Rosauro-Alcaraz
Samuel D. McDermott
Vivian Poulin
spellingShingle Samuel J. Witte
Salvador Rosauro-Alcaraz
Samuel D. McDermott
Vivian Poulin
Dark photon dark matter in the presence of inhomogeneous structure
Journal of High Energy Physics
Cosmology of Theories beyond the SM
Thermal Field Theory
author_facet Samuel J. Witte
Salvador Rosauro-Alcaraz
Samuel D. McDermott
Vivian Poulin
author_sort Samuel J. Witte
title Dark photon dark matter in the presence of inhomogeneous structure
title_short Dark photon dark matter in the presence of inhomogeneous structure
title_full Dark photon dark matter in the presence of inhomogeneous structure
title_fullStr Dark photon dark matter in the presence of inhomogeneous structure
title_full_unstemmed Dark photon dark matter in the presence of inhomogeneous structure
title_sort dark photon dark matter in the presence of inhomogeneous structure
publisher SpringerOpen
series Journal of High Energy Physics
issn 1029-8479
publishDate 2020-06-01
description Abstract Dark photon dark matter will resonantly convert into visible photons when the dark photon mass is equal to the plasma frequency of the ambient medium. In cosmological contexts, this transition leads to an extremely efficient, albeit short-lived, heating of the surrounding gas. Existing work in this field has been predominantly focused on understanding the implications of these resonant transitions in the limit that the plasma frequency of the Universe can be treated as being perfectly homogeneous, i.e. neglecting inhomogeneities in the electron number density. In this work we focus on the implications of heating from dark photon dark matter in the presence of inhomogeneous structure (which is particularly relevant for dark photons with masses in the range 10 −15 eV ≲ m A′ ≲ 10 −12 eV), emphasizing both the importance of inhomogeneous energy injection, as well as the sensitivity of cosmological observations to the inhomogeneities themselves. More specifically, we derive modified constraints on dark photon dark matter from the Ly-α forest, and show that the presence of inhomogeneities allows one to extend constraints to masses outside of the range that would be obtainable in the homogeneous limit, while only slightly relaxing their strength. We then project sensitivity for near-future cosmological surveys that are hoping to measure the 21cm transition in neutral hydrogen prior to reionization, and demonstrate that these experiments will be extremely useful in improving sensitivity to masses near ∼ 10 −14 eV, potentially by several orders of magnitude. Finally, we discuss implications for reionization, early star formation, and late-time y-type spectral distortions, and show that probes which are inherently sensitive to the inhomogeneous state of the Universe could resolve signatures unique to the light dark photon dark matter scenario, and thus offer a fantastic potential for a positive detection.
topic Cosmology of Theories beyond the SM
Thermal Field Theory
url http://link.springer.com/article/10.1007/JHEP06(2020)132
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