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1. Quantization of Axion-Gauge Couplings and Noninvertible Higher Symmetries

   https://doi.org/10.1103/PhysRevLett.132.121601  

   Choi, Yichul; Forslund, Matthew; Lam, Ho Tat; Shao, Shu-Heng (March 2024, Physical Review Letters)

   We derive model-independent quantization conditions on the axion couplings (sometimes known as the anomaly coefficients) to the standard model gauge group 1⁄2SUð3Þ × SUð2Þ × Uð1ÞY =Zq with q 1⁄4 1, 2, 3, 6. Using these quantization conditions, we prove that any QCD axion model to the right of the E=N 1⁄4 8=3 line on the jgaγγj-ma plot must necessarily face the axion domain wall problem in a postinflationary scenario. We further demonstrate the higher-group and noninvertible global symmetries in the standard model coupled to a single axion. These generalized global symmetries lead to universal bounds on the axion string tension and the monopole mass. If the axion were discovered in the future, our quantization conditions could be used to constrain the global form of the standard model gauge group. 

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2. Dynamical axion misalignment from the Witten effect

   https://doi.org/10.1007/JHEP02(2025)078  

   Banerjee, Abhishek; Buen-Abad, Manuel A (February 2025, Journal of High Energy Physics)

   A<sc>bstract</sc> We propose a relaxation mechanism for the initial misalignment angle of the pre-inflationary QCD axion with a large decay constant. The proposal addresses the challenges posed to the axion dark matter scenario by an overabundance of axions overclosing the Universe, as well as by isocurvature constraints. Many state-of-the-art experiments are searching for QCD axion dark matter with a decay constant as large as 10¹⁶GeV, motivating the need for a theoretical framework such as ours. In our model, hidden sector magnetic monopoles generated in the early Universe give the axion a large mass via the Witten effect, causing early oscillations that reduce the misalignment angle and axion abundance. As the hidden gauge symmetry breaks, its monopoles confine via cosmic strings, dissipating energy into the Standard Model and leading to monopole-antimonopole annihilation. This removes the monopole-induced mass, leaving only the standard QCD term. We consider the symmetry breaking pattern of SU(2)^′→ U(1)^′→ 1, leading to monopole and string formation respectively. We calculate the monopole abundance, their interactions with the axion field, and the necessary conditions for monopole-induced axion oscillations, while accounting for UV instanton effects. We present three model variations based on different symmetry breaking scales and show that they can accommodate an axion decay constant of up to 10¹⁶GeV with an inflationary scale of 10¹⁵GeV. The required alignment between monopole-induced and QCD axion potentials is achieved through a modest Nelson-Barr mechanism, avoiding overclosure without anthropic reasoning. 

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3. A cosmological solution to the doublet-triplet splitting problem

   https://doi.org/10.1007/JHEP02(2025)048  

   Csáki, Csaba; D’Agnolo, Raffaele Tito; Kuflik, Eric; Sesma, Pablo (February 2025, Journal of High Energy Physics)

   A<sc>bstract</sc> We propose a model that provides a simultaneous solution to the doublet-triplet splitting problem of grand unified theories, the electroweak hierarchy problem and the strong CP problem. The mechanism is based on the dynamics of two axion-like particles that would crunch the universe at the time of the QCD phase transition if triplets were light or had a VEV or if doublets were heavy or did not have a VEV. The only trace left at low energies are these two axion-like particles. They are weakly coupled to the Standard Model and could be detected at upcoming axion experiments or by a combination of neutron EDM measurements and the astrophysical detection of fuzzy dark matter. 

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4. Axion strings are superconducting

   https://doi.org/10.1007/JHEP06(2021)052  

   Fukuda, Hajime; Manohar, Aneesh V.; Murayama, Hitoshi; Telem, Ofri (June 2021, Journal of High Energy Physics)

   null (Ed.)

   A bstract We explore the cosmological consequences of the superconductivity of QCD axion strings. Axion strings can support a sizeable chiral electric current and charge density, which alters their early universe dynamics. We examine the possibility that shrinking axion string loops can become effectively stable remnants called vortons, supported by the repulsive electromagnetic force of the string current. We find that vortons in our scenario are generically unstable, and so do not pose a cosmological difficulty. Furthermore, if a primordial magnetic field (PMF) exists in the early universe, a large current is induced on axion strings, creating a significant drag force from interactions with the surrounding plasma. As a result, the strings are slowed down, which leads to an orders of magnitude enhancement in the number of strings per Hubble volume. Finally, we study potential implications for the QCD axion relic abundance. The QCD axion window is shifted by orders of magnitude in some parts of our parameter space. 

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5. Axion detection via superfluid 3He ferromagnetic phase and quantum measurement techniques

   https://doi.org/10.1007/JHEP09(2024)191  

   Chigusa, So; Kondo, Dan; Murayama, Hitoshi; Okabe, Risshin; Sudo, Hiroyuki (September 2024, Journal of High Energy Physics)

   A<sc>bstract</sc> We propose to use the nuclear spin excitation in the ferromagnetic A₁phase of the superfluid³He for the axion dark matter detection. This approach is striking in that it is sensitive to the axion-nucleon coupling, one of the most important features of the QCD axion introduced to solve the strong CP problem. We review a quantum mechanical description of the nuclear spin excitation and apply it to the estimation of the axion-induced spin excitation rate. We also describe a possible detection method of the spin excitation in detail and show that the combination of the squeezing of the final state with the Josephson parametric amplifier and the homodyne measurement can enhance the sensitivity. It turns out that this approach gives good sensitivity to the axion dark matter with the mass of$$ \mathcal{O} $$ $O$(1) μeV depending on the size of the external magnetic field. We estimate the parameters of experimental setups, e.g., the detector volume and the amplitude of squeezing, required to reach the QCD axion parameter space. 

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