Hidden photon dark matter in the light of XENON1T and stellar cooling

Alonso-Álvarez, Gonzalo; Ertas, Fatih; Jaeckel, Joerg; Kahlhoefer, Felix; Thormaehlen, Lennert J.

doi:10.1088/1475-7516/2020/11/029

Cited by 56 publications

(38 citation statements)

References 91 publications

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“…As we will discuss in the next section, some microscopic models with vector-like leptons can induce a suppressed axial vector coupling to the electron. Moreover, there is another loop process for the three-photon decay channel, χ 1 → χ 2 +3γ, but the corresponding decay rate is highly suppressed by Γ ∝ (∆m) 13 /(m 4 Z m 8 e ) [5], thus being consistent with X-ray bounds [37].…”

Section: Jhep01(2021)019mentioning

confidence: 70%

“…Quite recently, a tantalizing hint has been announced for the potential dark matter signals from the electron recoil events in the recoil energy, E R = 1 − 10 keV, from XENON1T experiment [1]. The origin of the Xenon excess has attracted interest from several groups [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17]. A simple explanation with the solar axion or the neutrino magnetic dipole moment has been put forward from the XENON1T collaboration, but both cases are inconsistent with the star cooling constraints, because the electron coupling to the axion or the neutrino magnetic dipole moment required for the Xenon excess exceeds them by the order of magnitude [1].…”

Section: Introductionmentioning

confidence: 99%

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Exothermic dark matter for XENON1T excess

Lee

2021

J. High Energ. Phys.

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Motivated by the recent excess in the electron recoil from XENON1T experiment, we consider the possibility of exothermic dark matter, which is composed of two states with mass splitting. The heavier state down-scatters off the electron into the lighter state, making an appropriate recoil energy required for the Xenon excess even for the standard Maxwellian velocity distribution of dark matter. Accordingly, we determine the mass difference between two component states of dark matter to the peak electron recoil energy at about 2.5 keV up to the detector resolution, accounting for the recoil events over ER = 2 − 3 keV, which are most significant. We include the effects of the phase-space enhancement and the atomic excitation factor to calculate the required scattering cross section for the Xenon excess. We discuss the implications of dark matter interactions in the effective theory for exothermic dark matter and a massive Z′ mediator and provide microscopic models realizing the required dark matter and electron couplings to Z′.

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Section: Jhep01(2021)019mentioning

confidence: 70%

Section: Introductionmentioning

confidence: 99%

Exothermic dark matter for XENON1T excess

Lee

2021

J. High Energ. Phys.

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“…Axion-like particles and dark photons -hints from XENON1T and stellar cooling Figure 1 shows the best-fit interpretation of the XENON1T excess in terms of dark photon absorption. The position and height of the peak are set by the dark photon mass and the kinetic mixing parameter, respectively, which are found to be m X = 2.8 keV and = 8.6 × 10 −16 at the best-fit point [6]. The width of the peak is determined by the detector resolution.…”

Section: Pos(ichep2020)635mentioning

confidence: 99%

“…A particularly appealing explanation is that the XENON1T excess is caused by the absorption of keV-scale bosonic dark matter particles, such as axion-like particles (ALPs) [5] or hidden photons [6], which would convert their entire rest mass into electronic recoil energy. Although such particles would be too light and too weakly coupled to be produced thermally in the early universe, they can be produced through a number of well-known non-thermal processes, such as the misalignment mechanism.…”

Section: Introductionmentioning

confidence: 99%

Axion-like particles and dark photons - hints from XENON1T and stellar cooling

Kahlhoefer¹

2021

Proceedings of 40th International Conference on High Energy Physics — PoS(ICHEP2020)

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The recently observed excess of electron recoil events in XENON1T can be interpreted as the absorption of bosonic dark matter particles in the keV range such as axion-like particles or dark photons. These same particles can also be produced in astrophysical systems such as horizontal branch stars or white dwarfs and account for the anomalous cooling rates observed in these systems. This talk considers the possibility that these phenomena have a common origin and discusses whether such an interpretation is preferred over the background hypothesis from a statistical point of view.

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“…In order to avoid large corrections to neutrino masses induced by large neutrino magnetic moments, some new symmetries can be introduced [21,26]. Moreover, there are many theoretical attempts to interpret the XENON1T signal assuming new physics beyond the SM such as, boosted dark matter [27][28][29][30][31][32], dark radiation [33,34], anomalous magnetic moment of muon [23,35], inelastic DM-electron scattering [36][37][38][39][40][41], axion-like DM [10,42]. Besides, there are some proposals using a gauged U (1) X extention of the SM, where a gauge boson Z contributes to dark matter (DM) [43][44][45][46][47][48][49][50][51].…”

Section: Jhep12(2020)194mentioning

confidence: 99%

Shedding new light on sterile neutrinos from XENON1T experiment

Shakeri

Hajkarim

Xue

2020

J. High Energ. Phys.

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The XENON1T collaboration recently reported the excess of events from recoil electrons, possibly giving an insight into new area beyond the Standard Model (SM) of particle physics. We try to explain this excess by considering effective interactions between the sterile neutrinos and the SM particles. In this paper, we present an effective model based on one-particle-irreducible interaction vertices at low energies that are induced from the SM gauge symmetric four-fermion operators at high energies. The effective interaction strength is constrained by the SM precision measurements, astrophysical and cosmological observations. We introduce a novel effective electromagnetic interaction between sterile neutrinos and SM neutrinos, which can successfully explain the XENON1T event rate through inelastic scattering of the sterile neutrino dark matter from Xenon electrons. We find that sterile neutrinos with masses around 90 keV and specific effective coupling can fit well with the XENON1T data where the best fit points preserving DM constraints and possibly describe the anomalies in other experiments.

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Hidden photon dark matter in the light of XENON1T and stellar cooling

Cited by 56 publications

References 91 publications

Exothermic dark matter for XENON1T excess

Exothermic dark matter for XENON1T excess

Axion-like particles and dark photons - hints from XENON1T and stellar cooling

Shedding new light on sterile neutrinos from XENON1T experiment

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