Abstract
We report results from searches for new physics with low-energy electronic recoil data recorded with the XENON1T detector. With an exposure of 0.65 t-y and an unprecedentedly low background rate of $76\pm2$ events/(t y keV) between 1 and 30 keV, the data enables sensitive searches for solar axions, an enhanced neutrino magnetic moment, and bosonic dark matter. An excess over known backgrounds is observed at low energies and most prominent between 2 and 3 keV. The solar axion model has a 3.4$\sigma$ significance, and a 3D 90% confidence surface is reported for axion couplings to electrons, photons, and nucleons. This surface is inscribed in the cuboid defined by $g_{ae}<3.8 \times 10^{-12}$, $g_{ae}g_{an}^{eff}<4.8\times 10^{-18}$, and $g_{ae}g_{a\gamma}<7.7\times10^{-22} GeV^{-1}$, and excludes either $g_{ae}=0$ or $g_{ae}g_{a\gamma}=g_{ae}g_{an}^{eff}=0$. The neutrino magnetic moment signal is similarly favored over background at 3.2$\sigma$ and a confidence interval of $\mu_{\nu} \in (1.4,2.9)\times10^{-11}\mu_B$ (90% C.L.) is reported. Both results are in strong tension with stellar constraints. The excess can also be explained by $\beta$ decays of tritium at 3.2$\sigma$ with a trace amount that can neither be confirmed nor excluded with current knowledge of its production and reduction mechanisms. The significances of the solar axion and neutrino magnetic moment hypotheses are reduced to 2.0$\sigma$ and 0.9$\sigma$, respectively, if an unconstrained tritium component is included in the fitting. With respect to bosonic dark matter, the excess favors a monoenergetic peak at ($2.3\pm0.2$) keV (68% C.L.) with a 3.0$\sigma$ global (4.0$\sigma$ local) significance. We also consider the possibility that $^{37}$Ar may be present in the detector and yield a 2.82 keV peak. Contrary to tritium, the $^{37}$Ar concentration can be tightly constrained and is found to be negligible.
Highlights
IntroductionA preponderance of astrophysical and cosmological evidence suggests that most of the matter content in the Universe is made up of a rarely interacting, nonluminous
We report on searches for new physics using low-energy electronic recoils in XENON1T
In a search for bosonic dark matter, world-leading constraints are placed on the interaction strengths of pseudoscalar and vector particles
Summary
A preponderance of astrophysical and cosmological evidence suggests that most of the matter content in the Universe is made up of a rarely interacting, nonluminous. Component called dark matter [1]. Several hypothetical dark matter particle candidates have been proposed with an assortment of couplings, masses, and detection signatures, dark matter has far eluded direct detection. The XENON1T experiment [2], employing a liquid-xenon time projection chamber (LXe TPC), was primarily designed to detect weakly interacting massive particle (WIMP) dark matter. Due to its unprecedentedly low background rate, large target mass, and low-energy threshold, XENON1T is sensitive to interactions from alternative dark matter candidates and to other physics beyond the Standard Model (SM). We report on searches for (1) axions produced in the Sun, (2) an enhancement of the neutrino magnetic moment using solar neutrinos, and (3) pseudoscalar and vector bosonic dark matter, including axion-like particles (ALPs) and dark photons
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