Quantum gravity effects on fermionic dark matter and gravitational waves
Quantum gravity effects on fermionic dark matter and gravitational waves
We explore the phenomenological consequences of breaking discrete global symmetries in quantum gravity (QG). We extend a previous scenario where discrete global symmetries are responsible for scalar dark matter (DM) and domain walls (DWs), to the case of fermionic DM, considered as a feebly interacting massive particle, which achieves the correct DM relic density via the freeze-in mechanism. Due to the mixing between DM and the standard model neutrinos, various indirect DM detection methods can be employed to constrain the QG scale, the scale of freeze-in, and the reheating temperature simultaneously. Since such QG symmetry breaking leads to DW annihilation, this may generate the characteristic gravitational wave background, and hence explain the recent observations of the gravitational wave spectrum by pulsar timing arrays. This work therefore highlights a tantalizing possibility of probing the effective scale of QG from observations.
hep-ph, astro-ph.HE, hep-th
King, Stephen F.
f8c616b7-0336-4046-a943-700af83a1538
Roshan, Rishav
8b76c007-f9b6-4568-8a45-741931b06bb5
Wang, Xin
e4b628e2-f2b1-4b33-a586-e5e8e9f63060
White, Graham
652445c5-e1e5-4ff7-84e1-a3bca45e75d0
Yamazak, Masahito
19211ccd-4c49-4074-a5f3-75d8e032beb3
King, Stephen F.
f8c616b7-0336-4046-a943-700af83a1538
Roshan, Rishav
8b76c007-f9b6-4568-8a45-741931b06bb5
Wang, Xin
e4b628e2-f2b1-4b33-a586-e5e8e9f63060
White, Graham
652445c5-e1e5-4ff7-84e1-a3bca45e75d0
Yamazak, Masahito
19211ccd-4c49-4074-a5f3-75d8e032beb3
[Unknown type: UNSPECIFIED]
Abstract
We explore the phenomenological consequences of breaking discrete global symmetries in quantum gravity (QG). We extend a previous scenario where discrete global symmetries are responsible for scalar dark matter (DM) and domain walls (DWs), to the case of fermionic DM, considered as a feebly interacting massive particle, which achieves the correct DM relic density via the freeze-in mechanism. Due to the mixing between DM and the standard model neutrinos, various indirect DM detection methods can be employed to constrain the QG scale, the scale of freeze-in, and the reheating temperature simultaneously. Since such QG symmetry breaking leads to DW annihilation, this may generate the characteristic gravitational wave background, and hence explain the recent observations of the gravitational wave spectrum by pulsar timing arrays. This work therefore highlights a tantalizing possibility of probing the effective scale of QG from observations.
Text
2311.12487v1
- Author's Original
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e-pub ahead of print date: 21 November 2023
Keywords:
hep-ph, astro-ph.HE, hep-th
Identifiers
Local EPrints ID: 485085
URI: http://eprints.soton.ac.uk/id/eprint/485085
PURE UUID: 76651a2e-dc08-4fda-b4b7-2c7e5cbbe5d4
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Date deposited: 29 Nov 2023 17:34
Last modified: 17 Mar 2024 06:10
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Contributors
Author:
Rishav Roshan
Author:
Xin Wang
Author:
Graham White
Author:
Masahito Yamazak
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