Springer : A Heavy QCD Axion and the Mirror World

Dunsky, David I.; Hall, Lawrence J.; Harigaya, Keisuke

doi:10.1007/JHEP02(2024)212

Article
Report number	arXiv:2302.04274
Title	A Heavy QCD Axion and the Mirror World
Author(s)	Dunsky, David I. (New York U., CCPP ; UC, Berkeley ; LBL, Berkeley) ; Hall, Lawrence J. (UC, Berkeley ; LBL, Berkeley) ; Harigaya, Keisuke (Chicago U. ; Chicago U., EFI ; Chicago U., KICP ; Tokyo U., IPMU ; CERN)
Publication	2024-02-27
Imprint	2023-02-08
Number of pages	36
Note	36 pages, 9 figures
In:	JHEP 2402 (2024) 212
DOI	10.1007/JHEP02(2024)212
Subject category	hep-ex ; Particle Physics - Experiment ; astro-ph.CO ; Astrophysics and Astronomy ; hep-ph ; Particle Physics - Phenomenology
Abstract	We study the mirror world with dark matter arising from the thermal freeze-out of the lightest, stable mirror particle -- the mirror electron. The dark matter abundance is achieved for mirror electrons of mass 225 GeV, fixing the mirror electroweak scale near $10^8$ GeV. This highly predictive scenario is realized by an axion that acts as a portal between the two sectors through its coupling to the QCD and mirror QCD sectors. The axion is more massive than the standard QCD axion due to additional contributions from mirror strong dynamics. Still, the strong CP problem is solved by this "heavy" axion due to the alignment of the QCD and mirror QCD potentials. Mirror entropy is transferred into the Standard Model sector via the axion portal, which alleviates overproduction of dark radiation from mirror glueball decays. This mirror scenario has a variety of signals: (1) primordial gravitational waves from the first-order mirror QCD phase transition occurring at a temperature near 35 GeV, (2) effects on large-scale structure from dark matter self-interactions from mirror QED, (3) dark radiation affecting the cosmic microwave background, and (4) the rare kaon decay, $K^+ \rightarrow (\pi^+ + \rm{axion})$. The first two signals do not depend on any fundamental free parameters of the theory while the latter two depend on a single free parameter, the axion decay constant.
Copyright/License	preprint: (License: CC BY 4.0) publication: © 2024-2025 The Authors (License: CC-BY-4.0), sponsored by SCOAP³

$Left panel: spectrum of mirror quarks and leptons for $v' = 8 \times 10^7$ GeV, which yields the observed dark matter abundance in $e'$ from freeze-out. The mass of the lightest mirror glueball, $S'$, is also shown, as is the relevant range of axion masses. Right panel: important temperatures in the thermal history of the universe. The mirror electroweak scale, $v'$, is also shown.$ $Contours for the direct (orange) and seesaw (blue) contributions to the light neutrino mass matrix, from the heavy mirror neutrino mass eigenstate $\nu'_i$, as defined in Eq.~(\ref{eq:Lnu}), with $v' = 8 \times 10^7$ GeV. The orange (blue) shaded regions give $m_{\nu_i}^{\rm dir} (m_{\nu_i}^{\rm ss})$ larger than 0.05 eV, and in many theories require unnatural cancellations. The red line has $m_{\nu_i}^{\rm dir} = m_{\nu_i}^{\rm ss}$, giving massless light neutrinos at tree level. The Singlet Model is constrained to live on this line for all three $\nu'_i$. In this theory, radiative neutrino masses of 0.05 eV can result along the solid part of the red line.$ $Decoupling temperature of SM and mirror sectors from the axion portal as a function of $f_a$. The orange curve shows the decoupling temperature from axion and mirror gluon interactions which become ineffective around the mirror QCD phase transition at $T_{\rm QCD'} \approx 34$ GeV. The blue curve shows the decoupling temperature from axion and mirror electron scatterings (Primakoff) which become ineffective at temperatures below $m_e' \approx 225$ GeV . For $f_a \lesssim 10^5$ GeV, the decoupling temperature from either interaction are comparable and occurs around $20-30$ GeV.$ Show more plots

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Record created 2023-04-20, last modified 2024-04-09

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