An axion (/ˈæksiɒn/) is a hypothetical elementary particle originally theorized in 1978 independently by Frank Wilczek and Steven Weinberg as the Goldstone boson of Peccei–Quinn theory, which had been proposed in 1977 to solve the strong CP problem in quantum chromodynamics (QCD). If axions exist and have low mass within a specific range, they are of interest as a possible component of cold dark matter.

Axion
InteractionsGravitational, electromagnetic, strong nuclear, weak nuclear
StatusHypothetical
SymbolA0, a, θ
Theorized1978, Wilczek and Weinberg
Mass 10−5 to 1 eV/c2 [1]
Electric charge0
Spin0

History

edit

Strong CP problem

edit

As shown by Gerard 't Hooft,[2] strong interactions of the standard model, QCD, possess a non-trivial vacuum structure[a] that in principle permits violation of the combined symmetries of charge conjugation and parity, collectively known as CP. Together with effects generated by weak interactions, the effective periodic strong CP-violating term, Θ, appears as a Standard Model input – its value is not predicted by the theory, but must be measured. However, large CP-violating interactions originating from QCD would induce a large electric dipole moment (EDM) for the neutron. Experimental constraints on the unobserved EDM implies CP violation from QCD must be extremely tiny and thus Θ must itself be extremely small. Since Θ could have any value between 0 and 2π, this presents a "naturalness" problem for the standard model. Why should this parameter find itself so close to zero? (Or, why should QCD find itself CP-preserving?) This question constitutes what is known as the strong CP problem.[b]

Prediction

edit

In 1977, Roberto Peccei and Helen Quinn postulated a more elegant solution to the strong CP problem, the Peccei–Quinn mechanism. The idea is to effectively promote Θ to a field. This is accomplished by adding a new global symmetry (called a Peccei–Quinn (PQ) symmetry) that becomes spontaneously broken. This results in a new particle, as shown independently by Frank Wilczek[5] and Steven Weinberg,[6] that fills the role of Θ, naturally relaxing the CP-violation parameter to zero. Wilczek named this new hypothesized particle the "axion" after a brand of laundry detergent because it "cleaned up" a problem,[7][8] while Weinberg called it "the higglet". Weinberg later agreed to adopt Wilczek's name for the particle.[8] Because it has a non-zero mass, the axion is a pseudo-Nambu–Goldstone boson.[9]

Axion dark matter

edit

QCD effects produce an effective periodic potential in which the axion field moves. [1] Expanding the potential about one of its minima, one finds that the product of the axion mass with the axion decay constant is determined by the topological susceptibility of the QCD vacuum. An axion with mass much less than 60 keV is long-lived and weakly interacting: A perfect dark matter candidate.

The oscillations of the axion field about the minimum of the effective potential, the so-called misalignment mechanism, generate a cosmological population of cold axions with an abundance depending on the mass of the axion.[10][11][12] With a mass above 5 μeV/c2 (10−11 times the electron mass) axions could account for dark matter, and thus be both a dark-matter candidate and a solution to the strong CP problem. If inflation occurs at a low scale and lasts sufficiently long, the axion mass can be as low as 1 peV/c2.[13][14][15]

There are two distinct scenarios in which the axion field begins its evolution, depending on the following two conditions:

(a) The PQ symmetry is spontaneously broken during inflation. This condition is realized whenever the axion energy scale is larger than the Hubble rate at the end of inflation.
(b) The PQ symmetry is never restored after its spontaneous breaking occurs. This condition is realized whenever the axion energy scale is larger than the maximum temperature reached in the post-inflationary Universe.

Broadly speaking, one of the two possible scenarios outlined in the two following subsections occurs:

Pre-inflationary scenario

edit

If both (a) and (b) are satisfied, cosmic inflation selects one patch of the Universe within which the spontaneous breaking of the PQ symmetry leads to a homogeneous value of the initial value of the axion field. In this "pre-inflationary" scenario, topological defects are inflated away and do not contribute to the axion energy density. However, other bounds that come from isocurvature modes severely constrain this scenario, which require a relatively low-energy scale of inflation to be viable.[16][17][18]

Post-inflationary scenario

edit

If at least one of the conditions (a) or (b) is violated, the axion field takes different values within patches that are initially out of causal contact, but that today populate the volume enclosed by our Hubble horizon. In this scenario, isocurvature fluctuations in the PQ field randomise the axion field, with no preferred value in the power spectrum.

The proper treatment in this scenario is to solve numerically the equation of motion of the PQ field in an expanding Universe, in order to capture all features coming from the misalignment mechanism, including the contribution from topological defects like "axionic" strings and domain walls. An axion mass estimate between 0.05 and 1.50 meV was reported by Borsanyi et al. (2016).[19] The result was calculated by simulating the formation of axions during the post-inflation period on a supercomputer.[20]

Progress in the late 2010s in determining the present abundance of a KSVZ-type axion[c] using numerical simulations lead to values between 0.02 and 0.1 meV,[23][24] although these results have been challenged by the details on the power spectrum of emitted axions from strings.[25]

Phenomenology of the axion field

edit

Searches

edit

The axion models originally proposed by Wilczek and by Weinberg chose axion coupling strengths that were so strong that they would have already been detected in prior experiments. It had been thought that the Peccei-Quinn mechanism for solving the strong CP problem required such large couplings. However, it was soon realized that "invisible axions" with much smaller couplings also work. Two such classes of models are known in the literature as KSVZ (KimShifmanVainshteinZakharov)[21][22] and DFSZ (DineFischlerSrednickiZhitnitsky).[26][27]

The very weakly coupled axion is also very light, because axion couplings and mass are proportional. Satisfaction with "invisible axions" changed when it was shown that any very light axion would have been overproduced in the early universe and therefore must be excluded.[10][11][12]

Maxwell's equations with axion modifications

edit

Pierre Sikivie computed how Maxwell's equations are modified in the presence of an axion in 1983.[28] He showed that these axions could be detected on Earth by converting them to photons, using a strong magnetic field, motivating a number of experiments. For example, the Axion Dark Matter Experiment converts axion dark matter to microwave photons, the CERN Axion Solar Telescope converts axions produced in the Sun's core to X-rays, and other experiments search for axions produced in laser light.[29] As of the early 2020s, there are dozens of proposed or ongoing experiments searching for axion dark matter.[30]

The equations of axion electrodynamics are typically written in "natural units", where the reduced Planck constant  , speed of light  , and permittivity of free space   all reduce to 1 when expressed in these "natural units". In this unit system, the electrodynamic equations are:

Name Equations
Gauss's law  
Gauss's law for magnetism  
Faraday's law  
Ampère–Maxwell law  
Axion field's equation of motion  

Above, a dot above a variable denotes its time derivative; the dot spaced between variables is the vector dot product; the factor   is the axion-to-photon coupling constant rendered in "natural units".

Alternative forms of these equations have been proposed, which imply completely different physical signatures. For example, Visinelli wrote a set of equations that imposed duality symmetry, assuming the existence of magnetic monopoles.[31] However, these alternative formulations are less theoretically motivated, and in many cases cannot even be derived from an action.

Analogous effect for topological insulators

edit

A term analogous to the one that would be added to Maxwell's equations to account for axions[32] also appears in recent (2008) theoretical models for topological insulators giving an effective axion description of the electrodynamics of these materials.[33]

This term leads to several interesting predicted properties including a quantized magnetoelectric effect.[34] Evidence for this effect has been given in THz spectroscopy experiments performed at the Johns Hopkins University on quantum regime thin film topological insulators developed at Rutgers University.[35]

In 2019, a team at the Max Planck Institute for Chemical Physics of Solids published their detection of an axion insulator phase of a Weyl semimetal material.[36] In the axion insulator phase, the material has an axion-like quasiparticle – an excitation of electrons that behave together as an axion – and its discovery demonstrates the consistency of axion electrodynamics as a description of the interaction of axion-like particles with electromagnetic fields. In this way, the discovery of axion-like quasiparticles in axion insulators provides motivation to use axion electrodynamics to search for the axion itself.[37]

Experiments

edit

Despite not yet having been found, the axion has been well studied for over 40 years, giving time for physicists to develop insight into axion effects that might be detected. Several experimental searches for axions are presently underway; most exploit axions' expected slight interaction with photons in strong magnetic fields. Axions are also one of the few remaining plausible candidates for dark matter particles, and might be discovered in some dark matter experiments.

 
Constraints on the axion's coupling to the photon
 
Constraints on the axion's dimensionless coupling to electrons

Direct conversion in a magnetic field

edit

Several experiments search for astrophysical axions by the Primakoff effect, which converts axions to photons and vice versa in electromagnetic fields.

The Axion Dark Matter Experiment (ADMX) at the University of Washington uses a strong magnetic field to detect the possible weak conversion of axions to microwaves.[38] ADMX searches the galactic dark matter halo[39] for axions resonant with a cold microwave cavity. ADMX has excluded optimistic axion models in the 1.9–3.53 μeV range.[40][41][42] From 2013 to 2018 a series of upgrades[43] were done and it is taking new data, including at 4.9–6.2 μeV. In December 2021 it excluded the 3.3–4.2 μeV range for the KSVZ model.[44][45]

Other experiments of this type include DMRadio,[46] HAYSTAC,[47] CULTASK,[48] and ORGAN.[49] HAYSTAC completed the first scanning run of a haloscope above 20 μeV in the late 2010s.[47]

Polarized light in a magnetic field

edit

The Italian PVLAS experiment searches for polarization changes of light propagating in a magnetic field. The concept was first put forward in 1986 by Luciano Maiani, Roberto Petronzio and Emilio Zavattini.[50] A rotation claim[51] in 2006 was excluded by an upgraded setup.[52] An optimized search began in 2014.

Light shining through walls

edit

Another technique is so called "light shining through walls",[53] where light passes through an intense magnetic field to convert photons into axions, which then pass through metal and are reconstituted as photons by another magnetic field on the other side of the barrier. Experiments by BFRS and a team led by Rizzo ruled out an axion cause.[54] GammeV saw no events, reported in a 2008 Physics Review Letter. ALPS I conducted similar runs,[55] setting new constraints in 2010; ALPS II began collecting data in May 2023.[56][57] OSQAR found no signal, limiting coupling,[58] and will continue.

Astrophysical axion searches

edit

Axion-like bosons could have a signature in astrophysical settings. In particular, several works have proposed axion-like particles as a solution to the apparent transparency of the Universe to TeV photons.[59][60] It has also been demonstrated that, in the large magnetic fields threading the atmospheres of compact astrophysical objects (e.g., magnetars), photons will convert much more efficiently. This would in turn give rise to distinct absorption-like features in the spectra detectable by early 21st century telescopes.[61] A new (2009) promising means is looking for quasi-particle refraction in systems with strong magnetic gradients. In particular, the refraction will lead to beam splitting in the radio light curves of highly magnetized pulsars and allow much greater sensitivities than currently achievable.[62] The International Axion Observatory (IAXO) is a proposed fourth generation helioscope.[63]

Axions can resonantly convert into photons in the magnetospheres of neutron stars.[64] The emerging photons lie in the GHz frequency range and can be potentially picked up in radio detectors, leading to a sensitive probe of the axion parameter space. This strategy has been used to constrain the axion–photon coupling in the 5–11 μeV mass range, by re-analyzing existing data from the Green Bank Telescope and the Effelsberg 100 m Radio Telescope.[65] A novel, alternative strategy consists in detecting the transient signal from the encounter between a neutron star and an axion minicluster in the Milky Way.[66]

Axions can be produced in the Sun's core when X-rays scatter in strong electric fields. The CAST solar telescope is underway, and has set limits on coupling to photons and electrons. Axions may also be produced within neutron stars by nucleon–nucleon bremsstrahlung. The subsequent decay of axions to gamma rays allows constraints on the axion mass to be placed from observations of neutron stars in gamma-rays using the Fermi Gamma-ray Space Telescope. From an analysis of four neutron stars, Berenji et al. (2016) obtained a 95% confidence interval upper limit on the axion mass of 0.079 eV.[67] In 2021 it has been also suggested[68][69] that a reported[70] excess of hard X-ray emission from a system of neutron stars known as the magnificent seven could be explained as axion emission.

In 2016, a theoretical team from Massachusetts Institute of Technology devised a possible way of detecting axions using a strong magnetic field that need be no stronger than that produced in an MRI scanning machine. It would show variation, a slight wavering, that is linked to the mass of the axion. Results from the ensuing experiment published in 2021 reported no evidence of axions in the mass range from 4.1x10-10 to 8.27x10-9 eV.[71]

In 2022 the polarized light measurements of Messier 87* by the Event Horizon Telescope were used to constrain the mass of the axion assuming that hypothetical clouds of axions could form around a black hole, rejecting the approximate 10−21 eV/c210−20 eV/c2 range of mass values.[72][73]

Searches for resonance effects

edit

Resonance effects may be evident in Josephson junctions[74] from a supposed high flux of axions from the galactic halo with mass of 110 μeV and density 0.05 GeV/cm3[75] compared to the implied dark matter density 0.3±0.1 GeV/cm3, indicating said axions would not have enough mass to be the sole component of dark matter. The ORGAN experiment plans to conduct a direct test of this result via the haloscope method.[49]

Dark matter recoil searches

edit

Dark matter cryogenic detectors have searched for electron recoils that would indicate axions. CDMS published in 2009 and EDELWEISS set coupling and mass limits in 2013. UORE and XMASS also set limits on solar axions in 2013. XENON100 used a 225-day run to set the best coupling limits to date and exclude some parameters.[76]

Nuclear spin precession

edit

While Schiff's theorem states that a static nuclear electric dipole moment (EDM) does not produce atomic and molecular EDMs,[77] the axion induces an oscillating nuclear EDM that oscillates at the Larmor frequency. If this nuclear EDM oscillation frequency is in resonance with an external electric field, a precession in the nuclear spin rotation occurs. This precession can be measured using precession magnetometry and if detected, would be evidence for Axions.[78]

An experiment using this technique is the Cosmic Axion Spin Precession Experiment (CASPEr).[79][80][81]

Searches at particle colliders

edit

Axions may also be produced at colliders, in particular in electron-positron collisions as well as in ultra-peripheral heavy ion collisions at the Large Hadron Collider at CERN, reinterpreting the light-by-light scattering process. Those searches are sensitive for rather large axion masses between 100 MeV/c2 and hundreds of GeV/c2. Assuming a coupling of axions to the Higgs boson, searches for anomalous Higgs boson decays into two axions can theoretically provide even stronger limits.[82]

Disputed detections

edit

It was reported in 2014 that evidence for axions may have been detected as a seasonal variation in observed X-ray emission that would be expected from conversion in the Earth's magnetic field of axions streaming from the Sun. Studying 15 years of data by the European Space Agency's XMM-Newton observatory, a research group at Leicester University noticed a seasonal variation for which no conventional explanation could be found. One potential explanation for the variation, described as "plausible" by the senior author of the paper, is the known seasonal variation in visibility to XMM-Newton of the sunward magnetosphere in which X-rays may be produced by axions from the Sun's core.[83][84]

This interpretation of the seasonal variation is disputed by two Italian researchers, who identify flaws in the arguments of the Leicester group that are said to rule out an interpretation in terms of axions. Most importantly, the scattering in angle assumed by the Leicester group to be caused by magnetic field gradients during the photon production, necessary to allow the X-rays to enter the detector that cannot point directly at the sun, would dissipate the flux so much that the probability of detection would be negligible.[85]

In 2013, Christian Beck suggested that axions might be detectable in Josephson junctions; and in 2014, he argued that a signature, consistent with a mass ≈110 μeV, had in fact been observed in several preexisting experiments.[86]

In 2020, the XENON1T experiment at the Gran Sasso National Laboratory in Italy reported a result suggesting the discovery of solar axions.[87] The results were not significant at the 5-sigma level required for confirmation, and other explanations of the data were possible though less likely.[88] New observations made in July 2022 after the observatory upgrade to XENONnT discarded the excess, thus ending the possibility of new particle discovery.[89][90]

Properties

edit

Predictions

edit

One theory of axions relevant to cosmology had predicted that they would have no electric charge, a very small mass in the range from 1 μeV/c2 to 1 eV/c2,[1] and very low interaction cross-sections for strong and weak forces. Because of their properties, axions would interact only minimally with ordinary matter. Axions would also change to and from photons in magnetic fields.

Cosmological implications

edit

The properties of the axion, such as the axion mass, decay constant, and abundance, all have implications for cosmology.[1]

Inflation theory suggests that if they exist, axions would be created abundantly during the Big Bang.[91] Because of a unique coupling to the instanton field of the primordial universe (the "misalignment mechanism"), an effective dynamical friction is created during the acquisition of mass, following cosmic inflation. This robs all such primordial axions of their kinetic energy.[citation needed]

Ultralight axion (ULA) with m ~ 10−22 eV/c2 is a kind of scalar field dark matter that seems to solve the small scale problems of CDM. A single ULA with a GUT scale decay constant provides the correct relic density without fine-tuning.[92]

Axions would also have stopped interaction with normal matter at a different moment after the Big Bang than other more massive dark particles.[why?] The lingering effects of this difference could perhaps be calculated and observed astronomically.[citation needed]

If axions have low mass, thus preventing other decay modes (since there are no lighter particles to decay into), the low coupling constant thus predicts that the axion is not scattered out of its state despite its small mass so that the universe would be filled with a very cold Bose–Einstein condensate of primordial axions. Hence, axions could plausibly explain the dark matter problem of physical cosmology.[93] Observational studies are underway, but they are not yet sufficiently sensitive to probe the mass regions if they are the solution to the dark matter problem with the fuzzy dark matter region starting to be probed via superradiance.[94] High mass axions of the kind searched for by Jain and Singh (2007)[95] would not persist in the modern universe. Moreover, if axions exist, scatterings with other particles in the thermal bath of the early universe unavoidably produce a population of hot axions.[96]

Low mass axions could have additional structure at the galactic scale. If they continuously fall into galaxies from the intergalactic medium, they would be denser in "caustic" rings, just as the stream of water in a continuously flowing fountain is thicker at its peak.[97] The gravitational effects of these rings on galactic structure and rotation might then be observable.[98][99] Other cold dark matter theoretical candidates, such as WIMPs and MACHOs, could also form such rings, but because such candidates are fermionic and thus experience friction or scattering among themselves, the rings would be less sharply defined.[citation needed]

João G. Rosa and Thomas W. Kephart suggested that axion clouds formed around unstable primordial black holes might initiate a chain of reactions that radiate electromagnetic waves, allowing their detection. When adjusting the mass of the axions to explain dark matter, the pair discovered that the value would also explain the luminosity and wavelength of fast radio bursts, being a possible origin for both phenomena.[100] In 2022 a similar hypothesis was used to constrain the mass of the axion from data of M87*.[citation needed]

In 2020, it was proposed that the axion field might actually have influenced the evolution of early Universe by creating more imbalance between the amounts of matter and antimatter – which possibly resolves the baryon asymmetry problem.[101]

Supersymmetry

edit

In supersymmetric theories the axion has both a scalar and a fermionic superpartner. The fermionic superpartner of the axion is called the axino, the scalar superpartner is called the saxion or dilaton. They are all bundled in a chiral superfield.

The axino has been predicted to be the lightest supersymmetric particle in such a model.[102] In part due to this property, it is also considered a candidate for dark matter.[103]

See also

edit

Footnotes

edit
  1. ^ This non-trivial vacuum structure solves a problem associated to the U(1) axial symmetry of QCD[3][4]
  2. ^ One simple solution to the strong CP problem exists: If at least one of the quarks of the standard model is massless, CP-violation becomes unobservable. However, empirical evidence strongly suggests that none of the quarks are massless. Consequently, particle theorists sought other resolutions to the problem of inexplicably conserved CP.
  3. ^ At present, physics literature discusses "invisible axion" mechanisms in two forms, one of them is called KSVZ for KimShifmanVainshteinZakharov.[21][22] See discussion in the "Searches" section, below.

References

edit
  1. ^ a b c d Peccei, R. D. (2008). "The Strong CP Problem and Axions". In Kuster, Markus; Raffelt, Georg; Beltrán, Berta (eds.). Axions: Theory, Cosmology, and Experimental Searches. Lecture Notes in Physics. Vol. 741. pp. 3–17. arXiv:hep-ph/0607268. doi:10.1007/978-3-540-73518-2_1. ISBN 978-3-540-73517-5. S2CID 119482294.
  2. ^ 't Hooft, Gerard (1976). "Symmetry breaking through Bell-Jackiw anomalies". Physical Review Letters. 37 (1).'t Hooft, Gerard (1976). "Computation of the quantum effects due to a four-dimensional pseudo-particle". Physical Review D. 14 (12). APS: 3432–3450. Bibcode:1976PhRvD..14.3432T. doi:10.1103/PhysRevD.14.3432.
  3. ^ Katz, Emanuel; Schwartz, Matthew D (28 August 2007). "An eta primer: solving the U(1) problem with AdS/QCD". Journal of High Energy Physics. 2007 (8): 077. arXiv:0705.0534. Bibcode:2007JHEP...08..077K. doi:10.1088/1126-6708/2007/08/077. S2CID 119863300.
  4. ^ Tanedo, Flip. "'t Hooft and η'ail Instantons and their applications" (PDF). Cornell University. Retrieved 2023-06-20.
  5. ^ Wilczek, Frank (1978). "Problem of Strong P and T Invariance in the Presence of Instantons". Physical Review Letters. 40 (5): 279–282. Bibcode:1978PhRvL..40..279W. doi:10.1103/PhysRevLett.40.279.
  6. ^ Weinberg, Steven (1978). "A New Light Boson?". Physical Review Letters. 40 (4): 223–226. Bibcode:1978PhRvL..40..223W. doi:10.1103/PhysRevLett.40.223.
  7. ^ Overbye, Dennis (17 June 2020). "Seeking dark matter, they detected another mystery". The New York Times.
  8. ^ a b Wilczek, Frank (7 January 2016). "Time's (almost) reversible arrow". Quanta Magazine. Retrieved 17 June 2020.
  9. ^ Miller, D. J.; Nevzorov, R. (2003). "The Peccei-Quinn Axion in the Next-to-Minimal Supersymmetric Standard Model". arXiv:hep-ph/0309143v1.
  10. ^ a b Preskill, J.; Wise, M.; Wilczek, F. (6 January 1983). "Cosmology of the invisible axion" (PDF). Physics Letters B. 120 (1–3): 127–132. Bibcode:1983PhLB..120..127P. CiteSeerX 10.1.1.147.8685. doi:10.1016/0370-2693(83)90637-8.
  11. ^ a b Abbott, L.; Sikivie, P. (1983). "A cosmological bound on the invisible axion". Physics Letters B. 120 (1–3): 133–136. Bibcode:1983PhLB..120..133A. CiteSeerX 10.1.1.362.5088. doi:10.1016/0370-2693(83)90638-X.
  12. ^ a b Dine, M.; Fischler, W. (1983). "The not-so-harmless axion". Physics Letters B. 120 (1–3): 137–141. Bibcode:1983PhLB..120..137D. doi:10.1016/0370-2693(83)90639-1.
  13. ^ di Luzio, L.; Nardi, E.; Giannotti, M.; Visinelli, L. (25 July 2020). "The landscape of QCD axion models". Physics Reports. 870: 1–117. arXiv:2003.01100. Bibcode:2020PhR...870....1D. doi:10.1016/j.physrep.2020.06.002. S2CID 211678181.
  14. ^ Graham, Peter W.; Scherlis, Adam (9 August 2018). "Stochastic axion scenario". Physical Review D. 98 (3): 035017. arXiv:1805.07362. Bibcode:2018PhRvD..98c5017G. doi:10.1103/PhysRevD.98.035017. S2CID 119432896.
  15. ^ Takahashi, Fuminobu; Yin, Wen; Guth, Alan H. (31 July 2018). "The QCD Axion Window and Low Scale Inflation". Physical Review D. 98 (1): 015042. arXiv:1805.08763. Bibcode:2018PhRvD..98a5042T. doi:10.1103/PhysRevD.98.015042. S2CID 54584447.
  16. ^ Crotty, P.; Garcia-Bellido, J.; Lesgourgues, J.; Riazuelo, A. (2003). "Bounds on isocurvature perturbations from CMB and LSS data". Physical Review Letters. 91 (17): 171301. arXiv:astro-ph/0306286. Bibcode:2003PhRvL..91q1301C. doi:10.1103/PhysRevLett.91.171301. PMID 14611330. S2CID 12140847.
  17. ^ Beltran, Maria; Garcia-Bellido, Juan; Lesgourgues, Julien; Liddle, Andrew R.; Slosar, Anze (2005). "Bayesian model selection and isocurvature perturbations". Physical Review D. 71 (6): 063532. arXiv:astro-ph/0501477. Bibcode:2005PhRvD..71f3532B. doi:10.1103/PhysRevD.71.063532. S2CID 2220608.
  18. ^ Beltran, Maria; Garcia-Bellido, Juan; Lesgourgues, Julien (2007). "Isocurvature bounds on axions revisited". Physical Review D. 75 (10): 103507. arXiv:hep-ph/0606107. Bibcode:2007PhRvD..75j3507B. doi:10.1103/PhysRevD.75.103507. S2CID 119451896.
  19. ^ Borsanyi, S.; Fodor, Z.; Guenther, J.; Kampert, K.-H.; Katz, S. D.; Kawanai, T.; et al. (3 November 2016). "Calculation of the axion mass based on high-temperature lattice quantum chromodynamics". Nature. 539 (7627): 69–71. Bibcode:2016Natur.539...69B. doi:10.1038/nature20115. PMID 27808190. S2CID 2943966.
  20. ^ Castelvecchi, Davide (3 November 2016). "Axion alert! Exotic-particle detector may miss out on dark matter". Nature. news. doi:10.1038/nature.2016.20925. S2CID 125299733.
  21. ^ a b Kim, J. E. (1979). "Weak-interaction singlet and strong CP invariance". Physical Review Letters. 43 (2): 103–107. Bibcode:1979PhRvL..43..103K. doi:10.1103/PhysRevLett.43.103.
  22. ^ a b Shifman, M.; Vainshtein, A.; Zakharov, V. (1980). "Can confinement ensure natural CP invariance of strong interactions?". Nuclear Physics B. 166 (3): 493–506. Bibcode:1980NuPhB.166..493S. doi:10.1016/0550-3213(80)90209-6.
  23. ^ Klaer, Vincent B.; Moore, Guy D. (2017). "The dark-matter axion mass". Journal of Cosmology and Astroparticle Physics. 2017 (11): 049. arXiv:1708.07521. Bibcode:2017JCAP...11..049K. doi:10.1088/1475-7516/2017/11/049. S2CID 119227153.
  24. ^ Buschmann, Malte; Foster, Joshua W.; Safdi, Benjamin R. (2020). "Early-Universe Simulations of the Cosmological Axion". Physical Review Letters. 124 (16): 161103. arXiv:1906.00967. Bibcode:2020PhRvL.124p1103B. doi:10.1103/PhysRevLett.124.161103. PMID 32383908. S2CID 174797749.
  25. ^ Gorghetto, Marco; Hardy, Edward; Villadoro, Giovanni (2021). "More axions from strings". SciPost Physics. 10 (2): 050. arXiv:2007.04990. Bibcode:2021ScPP...10...50G. doi:10.21468/SciPostPhys.10.2.050. S2CID 220486728.
  26. ^ Dine, M.; Fischler, W.; Srednicki, M. (1981). "A simple solution to the strong CP problem with a harmless axion". Physics Letters B. 104 (3): 199–202. Bibcode:1981PhLB..104..199D. doi:10.1016/0370-2693(81)90590-6.
  27. ^ Zhitnitsky, A. (1980). "On possible suppression of the axion–hadron interactions". Soviet Journal of Nuclear Physics. 31: 260.
  28. ^ Sikivie, P. (17 October 1983). "Experimental Tests of the 'Invisible' Axion". Physical Review Letters. 51 (16): 1413. Bibcode:1983PhRvL..51.1415S. doi:10.1103/physrevlett.51.1415.
  29. ^ "OSQAR". CERN. 2017. Retrieved 3 October 2017.
  30. ^ Adams, C. B.; et al. (2022). "Axion Dark Matter". arXiv:2203.14923 [hep-ex].
  31. ^ Visinelli, L. (2013). "Axion-electromagnetic waves". Modern Physics Letters A. 28 (35): 1350162. arXiv:1401.0709. Bibcode:2013MPLA...2850162V. doi:10.1142/S0217732313501629. S2CID 119221244.
  32. ^ Wilczek, Frank (4 May 1987). "Two applications of axion electrodynamics". Physical Review Letters. 58 (18): 1799–1802. Bibcode:1987PhRvL..58.1799W. doi:10.1103/PhysRevLett.58.1799. PMID 10034541.
  33. ^ Qi, Xiao-Liang; Hughes, Taylor L.; Zhang, Shou-Cheng (24 November 2008). "Topological field theory of time-reversal invariant insulators". Physical Review B. 78 (19): 195424. arXiv:0802.3537. Bibcode:2008PhRvB..78s5424Q. doi:10.1103/PhysRevB.78.195424. S2CID 117659977.
  34. ^ Franz, Marcel (24 November 2008). "High-energy physics in a new guise". Physics. 1: 36. Bibcode:2008PhyOJ...1...36F. doi:10.1103/Physics.1.36.
  35. ^ Wu, Liang; Salehi, M.; Koirala, N.; Moon, J.; Oh, S.; Armitage, N. P. (2 December 2016). "Quantized Faraday and Kerr rotation and axion electrodynamics of a 3D topological insulator". Science. 354 (6316): 1124–1127. arXiv:1603.04317. Bibcode:2016Sci...354.1124W. doi:10.1126/science.aaf5541. PMID 27934759. S2CID 25311729.
  36. ^ Gooth, J.; Bradlyn, B.; Honnali, S.; Schindler, C.; Kumar, N.; Noky, J.; et al. (7 October 2019). "Axionic charge-density wave in the Weyl semimetal (TaSe4)2I". Nature. 575 (7782): 315–319. arXiv:1906.04510. Bibcode:2019Natur.575..315G. doi:10.1038/s41586-019-1630-4. PMID 31590178. S2CID 184487056.
  37. ^ Fore, Meredith (22 November 2019). "Physicists have finally seen traces of a long-sought particle. Here's why that's a Big Deal". Live Science. Future US, Inc. Retrieved 25 February 2020.
  38. ^ Chu, Jennifer. "Team simulates a magnetar to seek dark matter particle". Phys.org (Press release). Massachusetts Institute of Technology.
  39. ^ Duffy, L. D.; Sikivie, P.; Tanner, D. B.; Bradley, R. F.; Hagmann, C.; Kinion, D.; et al. (2006). "High resolution search for dark-matter axions". Physical Review D. 74 (1): 12006. arXiv:astro-ph/0603108. Bibcode:2006PhRvD..74a2006D. doi:10.1103/PhysRevD.74.012006. S2CID 35236485.
  40. ^ Asztalos, S. J.; Carosi, G.; Hagmann, C.; Kinion, D.; van Bibber, K.; Hoskins, J.; et al. (2010). "SQUID-based microwave cavity search for dark-matter axions" (PDF). Physical Review Letters. 104 (4): 41301. arXiv:0910.5914. Bibcode:2010PhRvL.104d1301A. doi:10.1103/PhysRevLett.104.041301. PMID 20366699. S2CID 35365606.
  41. ^ "ADMX | Axion Dark Matter eXperiment". Physics. phys.washington.edu. Seattle, Washington: University of Washington. Retrieved 10 May 2014.
  42. ^ "Phase 1 results". Physics. phys.washington.edu. Seattle, Washington: University of Washington. 4 March 2006.
  43. ^ Tanner, David B.; Sullivan, Neil (2019). The "Gen 2" Axion Dark Matter Experiment (ADMX) (Technical report). doi:10.2172/1508642. OSTI 1508642. S2CID 204183272.
  44. ^ Bartram, C.; Braine, T.; Burns, E.; Cervantes, R.; Crisosto, N.; Du, N.; et al. (23 December 2021). "Search for Invisible Axion Dark Matter in the 3.3 – 4.2 μ eV Mass Range". Physical Review Letters. 127 (26): 261803. arXiv:2110.06096. Bibcode:2021PhRvL.127z1803B. doi:10.1103/PhysRevLett.127.261803. PMID 35029490. S2CID 238634307.
  45. ^ Stephens, Marric (23 December 2021). "Tightening the Net on Two Kinds of Dark Matter". Physics. 14. Bibcode:2021PhyOJ..14.s164S. doi:10.1103/Physics.14.s164. S2CID 247277808.
  46. ^ Silva-Feaver, Maximiliano; Chaudhuri, Saptarshi; Cho, Hsaio-Mei; Dawson, Carl; Graham, Peter; Irwin, Kent; Kuenstner, Stephen; Li, Dale; Mardon, Jeremy; Moseley, Harvey; Mule, Richard; Phipps, Arran; Rajendran, Surjeet; Steffen, Zach; Young, Betty (June 2017). "Design Overview of DM Radio Pathfinder Experiment". IEEE Transactions on Applied Superconductivity. 27 (4): 1–4. arXiv:1610.09344. Bibcode:2017ITAS...2731425S. doi:10.1109/TASC.2016.2631425. S2CID 29416513.
  47. ^ a b Brubaker, B. M.; Zhong, L.; Gurevich, Y. V.; Cahn, S. B.; Lamoreaux, S. K.; Simanovskaia, M.; et al. (9 February 2017). "First Results from a Microwave Cavity Axion Search at 24 μ eV". Physical Review Letters. 118 (6): 061302. arXiv:1610.02580. Bibcode:2017PhRvL.118f1302B. doi:10.1103/physrevlett.118.061302. PMID 28234529. S2CID 6509874.
  48. ^ Petrakou, Eleni (2017). "Haloscope searches for dark matter axions at the Center for Axion and Precision Physics Research". EPJ Web of Conferences. 164: 01012. arXiv:1702.03664. Bibcode:2017EPJWC.16401012P. doi:10.1051/epjconf/201716401012. S2CID 119381143.
  49. ^ a b McAllister, Ben T.; Flower, Graeme; Ivanov, Eugene N.; Goryachev, Maxim; Bourhill, Jeremy; Tobar, Michael E. (December 2017). "The ORGAN experiment: An axion haloscope above 15 GHz". Physics of the Dark Universe. 18: 67–72. arXiv:1706.00209. Bibcode:2017PDU....18...67M. doi:10.1016/j.dark.2017.09.010. S2CID 118887710.
  50. ^ Maiani, L.; Petronzio, R.; Zavattini, E. (7 August 1986). "Effects of nearly massless, spin-zero particles on light propagation in a magnetic field" (PDF). Physics Letters B. 175 (3): 359–363. Bibcode:1986PhLB..175..359M. doi:10.1016/0370-2693(86)90869-5. CERN-TH.4411/86.
  51. ^ Reucroft, Steve; Swain, John (5 October 2006). "Axion signature may be QED". CERN Courier. Archived from the original on 20 August 2008.
  52. ^ Zavattini, E.; et al. (PVLAS Collaboration) (2006). "Experimental Observation of Optical Rotation Generated in Vacuum by a Magnetic Field". Physical Review Letters. 96 (11): 110406. arXiv:hep-ex/0507107. Bibcode:2006PhRvL..96k0406Z. doi:10.1103/PhysRevLett.96.110406. PMID 16605804.
  53. ^ Ringwald, A. (16–21 October 2001). "Fundamental Physics at an X-Ray Free Electron Laser". Electromagnetic Probes of Fundamental Physics – Proceedings of the Workshop. Workshop on Electromagnetic Probes of Fundamental Physics. Erice, Italy. pp. 63–74. arXiv:hep-ph/0112254. doi:10.1142/9789812704214_0007. ISBN 978-981-238-566-6.
  54. ^ Robilliard, C.; Battesti, R.; Fouche, M.; Mauchain, J.; Sautivet, A.-M.; Amiranoff, F.; Rizzo, C. (2007). "No 'light shining through a wall': Results from a photoregeneration experiment". Physical Review Letters. 99 (19): 190403. arXiv:0707.1296. Bibcode:2007PhRvL..99s0403R. doi:10.1103/PhysRevLett.99.190403. PMID 18233050. S2CID 23159010.
  55. ^ Ehret, Klaus; Frede, Maik; Ghazaryan, Samvel; Hildebrandt, Matthias; Knabbe, Ernst-Axel; Kracht, Dietmar; et al. (May 2010). "New ALPS results on hidden-sector lightweights". Physics Letters B. 689 (4–5): 149–155. arXiv:1004.1313. Bibcode:2010PhLB..689..149E. doi:10.1016/j.physletb.2010.04.066. S2CID 58898031.
  56. ^ Diaz Ortiz, M.; Gleason, J.; Grote, H.; Hallal, A.; Hartman, M.T.; Hollis, H.; Isleif, K.-S.; James, A.; Karan, K.; Kozlowski, T.; Lindner, A.; Messineo, G.; Mueller, G.; Põld, J.H.; Smith, R.C.G.; Spector, A.D.; Tanner, D.B.; Wei, L.-W.; Willke, B. (March 2022). "Design of the ALPS II optical system". Physics of the Dark Universe. 35: 100968. arXiv:2009.14294. Bibcode:2022PDU....3500968D. doi:10.1016/j.dark.2022.100968. S2CID 222067049.
  57. ^ "'Light shining through a wall' experiment ALPS starts searching for dark matter". DESY. 2023-05-23. Retrieved 2024-09-25.
  58. ^ Pugnat, P.; Ballou, R.; Schott, M.; Husek, T.; Sulc, M.; Deferne, G.; et al. (August 2014). "Search for weakly interacting sub-eV particles with the OSQAR laser-based experiment: Results and perspectives". The European Physical Journal C. 74 (8): 3027. arXiv:1306.0443. Bibcode:2014EPJC...74.3027P. doi:10.1140/epjc/s10052-014-3027-8. S2CID 29889038.
  59. ^ De Angelis, A.; Mansutti, O.; Roncadelli, M. (2007). "Evidence for a new light spin-zero boson from cosmological gamma-ray propagation?". Physical Review D. 76 (12): 121301. arXiv:0707.4312. Bibcode:2007PhRvD..76l1301D. doi:10.1103/PhysRevD.76.121301. S2CID 119152884.
  60. ^ De Angelis, A.; Mansutti, O.; Persic, M.; Roncadelli, M. (2009). "Photon propagation and the very high energy gamma-ray spectra of blazars: How transparent is the Universe?". Monthly Notices of the Royal Astronomical Society: Letters. 394 (1): L21–L25. arXiv:0807.4246. Bibcode:2009MNRAS.394L..21D. doi:10.1111/j.1745-3933.2008.00602.x. S2CID 18184567.
  61. ^ Chelouche, Doron; Rabadan, Raul; Pavlov, Sergey S.; Castejon, Francisco (2009). "Spectral signatures of photon–particle oscillations from celestial objects". The Astrophysical Journal. Supplement Series. 180 (1): 1–29. arXiv:0806.0411. Bibcode:2009ApJS..180....1C. doi:10.1088/0067-0049/180/1/1. S2CID 5018245.
  62. ^ Chelouche, Doron; Guendelman, Eduardo I. (2009). "Cosmic analogs of the Stern–Gerlach experiment and the detection of light bosons". The Astrophysical Journal. 699 (1): L5–L8. arXiv:0810.3002. Bibcode:2009ApJ...699L...5C. doi:10.1088/0004-637X/699/1/L5. S2CID 11868951.
  63. ^ "The International Axion Observatory". CERN. Retrieved 19 March 2016.
  64. ^ Pshirkov, Maxim S.; Popov, Sergei B. (2009). "Conversion of Dark matter axions to photons in magnetospheres of neutron stars". Journal of Experimental and Theoretical Physics. 108 (3): 384–388. arXiv:0711.1264. Bibcode:2009JETP..108..384P. doi:10.1134/S1063776109030030. S2CID 119269835.
  65. ^ Foster, Joshua W.; Kahn, Yonatan; Macias, Oscar; Sun, Zhiquan; Eatough, Ralph P.; Kondratiev, Vladislav I.; Peters, Wendy M.; Weniger, Christoph; Safdi, Benjamin R. (2020). "Green Bank and Effelsberg Radio Telescope Searches for Axion Dark Matter Conversion in Neutron Star Magnetospheres". Physical Review Letters. 125 (17): 171301. arXiv:2004.00011. Bibcode:2020PhRvL.125q1301F. doi:10.1103/PhysRevLett.125.171301. PMID 33156637. S2CID 214743261.
  66. ^ Edwards, Thomas D. P.; Kavanagh, Bradley J.; Visinelli, Luca; Weniger, Christoph (2021). "Transient Radio Signatures from Neutron Star Encounters with QCD Axion Miniclusters". Physical Review Letters. 127 (13): 131103. arXiv:2011.05378. Bibcode:2021PhRvL.127m1103E. doi:10.1103/PhysRevLett.127.131103. PMID 34623827. S2CID 226300099.
  67. ^ Berenji, B.; Gaskins, J.; Meyer, M. (2016). "Constraints on axions and axionlike particles from Fermi Large Area Telescope observations of neutron stars". Physical Review D. 93 (14): 045019. arXiv:1602.00091. Bibcode:2016PhRvD..93d5019B. doi:10.1103/PhysRevD.93.045019. S2CID 118723146.
  68. ^ Buschmann, Malte; Co, Raymond T.; Dessert, Christopher; Safdi, Benjamin R. (12 January 2021). "Axion Emission Can Explain a New Hard X-Ray Excess from Nearby Isolated Neutron Stars". Physical Review Letters. 126 (2): 021102. arXiv:1910.04164. Bibcode:2021PhRvL.126b1102B. doi:10.1103/PhysRevLett.126.021102. PMID 33512228. S2CID 231764983.
  69. ^ O'Callaghan, Jonathan (2021-10-19). "A Hint of Dark Matter Sends Physicists Looking to the Skies". Quanta Magazine. Retrieved 2021-10-25.
  70. ^ Dessert, Christopher; Foster, Joshua W.; Safdi, Benjamin R. (November 2020). "Hard X-Ray Excess from the Magnificent Seven Neutron Stars". The Astrophysical Journal. 904 (1): 42. arXiv:1910.02956. Bibcode:2020ApJ...904...42D. doi:10.3847/1538-4357/abb4ea. S2CID 203902766.
  71. ^ Salemi, Chiara P.; Foster, Joshua W.; Ouellet, Jonathan L.; Gavin, Andrew; Pappas, Kaliroë M. W.; Cheng, Sabrina; Richardson, Kate A.; Henning, Reyco; Kahn, Yonatan; Nguyen, Rachel; Rodd, Nicholas L.; Safdi, Benjamin R.; Winslow, Lindley (2021-08-17). "Search for Low-Mass Axion Dark Matter with ABRACADABRA-10 cm". Physical Review Letters. 127 (8): 081801. arXiv:2102.06722. Bibcode:2021PhRvL.127h1801S. doi:10.1103/PhysRevLett.127.081801. PMID 34477408.
  72. ^ Chen, Yifan; Liu, Yuxin; Lu, Ru-Sen; Mizuno, Yosuke; Shu, Jing; Xue, Xiao; Yuan, Qiang; Zhao, Yue (17 March 2022). "Stringent axion constraints with Event Horizon Telescope polarimetric measurements of M87⋆". Nature Astronomy. 6 (5): 592–598. arXiv:2105.04572. Bibcode:2022NatAs...6..592C. doi:10.1038/s41550-022-01620-3. S2CID 247188135.
  73. ^ Kruesi, Liz (17 March 2022). "How light from black holes is narrowing the search for axions". Science News.
  74. ^ Beck, Christian (2 December 2013). "Possible Resonance Effect of Axionic Dark Matter in Josephson Junctions". Physical Review Letters. 111 (23): 1801. arXiv:1309.3790. Bibcode:2013PhRvL.111w1801B. doi:10.1103/PhysRevLett.111.231801. PMID 24476255. S2CID 23845250.
  75. ^ Moskvitch, Katia. "Hints of cold dark matter pop up in 10 year-old circuit". New Scientist Magazine. Retrieved 3 December 2013.
  76. ^ Aprile, E.; et al. (9 September 2014). "First axion results from the XENON100 experiment". Physical Review D. 90 (6): 062009. arXiv:1404.1455. Bibcode:2014PhRvD..90f2009A. doi:10.1103/PhysRevD.90.062009. S2CID 55875111.
  77. ^ Commins, Eugene D.; Jackson, J. D.; DeMille, David P. (June 2007). "The electric dipole moment of the electron: An intuitive explanation for the evasion of Schiff's theorem". American Journal of Physics. 75 (6): 532–536. Bibcode:2007AmJPh..75..532C. doi:10.1119/1.2710486.
  78. ^ Flambaum, V. V.; Tan, H. B. Tran (27 December 2019). "Oscillating nuclear electric dipole moment induced by axion dark matter produces atomic and molecular electric dipole moments and nuclear spin rotation". Physical Review D. 100 (11): 111301. arXiv:1904.07609. Bibcode:2019PhRvD.100k1301F. doi:10.1103/PhysRevD.100.111301. S2CID 119303702.
  79. ^ Budker, Dmitry; Graham, Peter W.; Ledbetter, Micah; Rajendran, Surjeet; Sushkov, Alexander O. (19 May 2014). "Proposal for a Cosmic Axion Spin Precession Experiment (CASPEr)". Physical Review X. 4 (2): 021030. arXiv:1306.6089. Bibcode:2014PhRvX...4b1030B. doi:10.1103/PhysRevX.4.021030. S2CID 118351193.
  80. ^ Garcon, Antoine; Aybas, Deniz; Blanchard, John W; Centers, Gary; Figueroa, Nataniel L; Graham, Peter W; et al. (January 2018). "The cosmic axion spin precession experiment (CASPEr): a dark-matter search with nuclear magnetic resonance". Quantum Science and Technology. 3 (1): 014008. arXiv:1707.05312. Bibcode:2018QS&T....3a4008G. doi:10.1088/2058-9565/aa9861. S2CID 51686418.
  81. ^ Aybas, Deniz; Adam, Janos; Blumenthal, Emmy; Gramolin, Alexander V.; Johnson, Dorian; Kleyheeg, Annalies; et al. (9 April 2021). "Search for Axionlike Dark Matter Using Solid-State Nuclear Magnetic Resonance". Physical Review Letters. 126 (14): 141802. arXiv:2101.01241. Bibcode:2021PhRvL.126n1802A. doi:10.1103/PhysRevLett.126.141802. PMID 33891466. S2CID 230524028.
  82. ^ Bauer, Martin; Neubert, Matthias; Thamm, Andrea (December 2017). "Collider Probes of Axion-Like Particles". Journal of High Energy Physics. 2017 (12): 44. arXiv:1708.00443. Bibcode:2017JHEP...12..044B. doi:10.1007/JHEP12(2017)044. S2CID 119422560.
  83. ^ Sample, Ian (16 October 2014). "Dark matter may have been detected – streaming from sun's core". The Guardian. London, UK. Retrieved 16 October 2014.
  84. ^ Fraser, G. W.; Read, A. M.; Sembay, S.; Carter, J. A.; Schyns, E. (2014). "Potential solar axion signatures in X-ray observations with the XMM-Newton observatory". Monthly Notices of the Royal Astronomical Society. 445 (2): 2146–2168. arXiv:1403.2436. Bibcode:2014MNRAS.445.2146F. doi:10.1093/mnras/stu1865. S2CID 56328280.
  85. ^ Roncadelli, M.; Tavecchio, F. (2015). "No axions from the Sun". Monthly Notices of the Royal Astronomical Society: Letters. 450 (1): L26–L28. arXiv:1411.3297. Bibcode:2015MNRAS.450L..26R. doi:10.1093/mnrasl/slv040. S2CID 119275136.
  86. ^ Beck, Christian (2015). "Axion mass estimates from resonant Josephson junctions". Physics of the Dark Universe. 7–8: 6–11. arXiv:1403.5676. Bibcode:2015PDU.....7....6B. doi:10.1016/j.dark.2015.03.002. S2CID 119239296.
  87. ^ Aprile, E.; et al. (2020-06-17). "Observation of excess electronic recoil events in XENON1T". Physical Review D. 102: 072004. arXiv:2006.09721. doi:10.1103/PhysRevD.102.072004. S2CID 222338600.
  88. ^ Vagnozzi, Sunny; Visinelli, Luca; Brax, Philippe; Davis, Anne-Christine; Sakstein, Jeremy (15 September 2021). "Direct detection of dark energy: The XENON1T excess and future prospects". Physical Review D. 104 (6): 063023. arXiv:2103.15834. Bibcode:2021PhRvD.104f3023V. doi:10.1103/PhysRevD.104.063023. S2CID 232417159.
  89. ^ Conover, Emily (22 July 2022). "A new dark matter experiment quashed earlier hints of new particles". Science News.
  90. ^ Aprile, E.; Abe, K.; Agostini, F.; Maouloud, S. Ahmed; Althueser, L.; Andrieu, B.; Angelino, E.; Angevaare, J. R.; Antochi, V. C.; Martin, D. Antón; Arneodo, F. (2022-07-22). "Search for New Physics in Electronic Recoil Data from XENONnT". Physical Review Letters. 129 (16): 161805. arXiv:2207.11330. Bibcode:2022PhRvL.129p1805A. doi:10.1103/PhysRevLett.129.161805. PMID 36306777. S2CID 251040527.
  91. ^ Redondo, J.; Raffelt, G.; Viaux Maira, N. (2012). "Journey at the axion meV mass frontier". Journal of Physics: Conference Series. 375 (2): 022004. Bibcode:2012JPhCS.375b2004R. doi:10.1088/1742-6596/375/1/022004.
  92. ^ Marsh, David J.E. (2016). "Axion cosmology". Physics Reports. 643: 1–79. arXiv:1510.07633. Bibcode:2016PhR...643....1M. doi:10.1016/j.physrep.2016.06.005. S2CID 119264863.
  93. ^ Sikivie, P. (2009). "Dark matter axions". International Journal of Modern Physics A. 25 (203): 554–563. arXiv:0909.0949. Bibcode:2010IJMPA..25..554S. doi:10.1142/S0217751X10048846. S2CID 1058708.
  94. ^ Davoudiasl, Hooman; Denton, Peter (2019). "Ultralight Boson Dark Matter and Event Horizon Telescope Observations of M87". Physical Review Letters. 123 (2): 021102. arXiv:1904.09242. Bibcode:2019PhRvL.123b1102D. doi:10.1103/PhysRevLett.123.021102. PMID 31386502. S2CID 126147949.
  95. ^ Jain, P. L.; Singh, G. (2007). "Search for new particles decaying into electron pairs of mass below 100 MeV/c2". Journal of Physics G. 34 (1): 129–138. Bibcode:2007JPhG...34..129J. doi:10.1088/0954-3899/34/1/009. possible early evidence of 7±1 and 19±1 MeV axions of less than 10−13 s lifetime
  96. ^ Salvio, Alberto; Strumia, Alessandro; Xue, Wei (2014). "Thermal axion production". Journal of Cosmology and Astroparticle Physics. 2014 (1): 11. arXiv:1310.6982. Bibcode:2014JCAP...01..011S. doi:10.1088/1475-7516/2014/01/011. S2CID 67775116.
  97. ^ Sikivie, P. (1997). Dark matter axions and caustic rings (Technical report). doi:10.2172/484584. OSTI 484584. S2CID 13840214.
  98. ^ Sikivie, P. "Pictures of alleged triangular structure in Milky Way".[self-published source?]
  99. ^ Duffy, Leanne D.; Tanner, David B.; Van Bibber, Karl A. (2010). The Milky Way's Dark Matter Distribution and Consequences for Axion Detection. Axions 2010. AIP Conference Proceedings. Vol. 1274. pp. 85–90. Bibcode:2010AIPC.1274...85D. doi:10.1063/1.3489563.
  100. ^ Rosa, João G.; Kephart, Thomas W. (2018). "Stimulated axion decay in superradiant clouds around primordial black holes". Physical Review Letters. 120 (23): 231102. arXiv:1709.06581. Bibcode:2018PhRvL.120w1102R. doi:10.1103/PhysRevLett.120.231102. PMID 29932720. S2CID 49382336.
  101. ^ Anonymous (2020-03-19). "Axions Could Explain Baryon Asymmetry". Physics. 13 (11): s38. arXiv:1910.02080. doi:10.1103/PhysRevLett.124.111602. PMID 32242736.
  102. ^ Nobutaka, Abe; Moroi, Takeo & Yamaguchi, Masahiro (2002). "Anomaly-Mediated Supersymmetry Breaking with Axion". Journal of High Energy Physics. 1 (1): 10. arXiv:hep-ph/0111155. Bibcode:2002JHEP...01..010A. doi:10.1088/1126-6708/2002/01/010. S2CID 15280422.
  103. ^ Hooper, Dan; Wang, Lian-Tao (2004). "Possible evidence for axino dark matter in the galactic bulge". Physical Review D. 70 (6): 063506. arXiv:hep-ph/0402220. Bibcode:2004PhRvD..70f3506H. doi:10.1103/PhysRevD.70.063506. S2CID 118153564.

Sources

edit
edit