Interpretation of XENON1T excess with MeV boosted dark matter

Abstract

The XENON1T excess of keV electron recoil events may be induced by the scattering of electrons and long-lived particles with MeV mass and high-speed. We consider a tangible model composed of two scalar MeV dark matter (DM) particles SA and SB to interpret the XENON1T keV excess via boosted SB. A small mass splitting mSA-mSB>0 is introduced and the boosted SB can be produced by the dark annihilation process of SA SA φ SB SB via a resonant scalar φ. The SB-electron scattering is intermediated by a vector boson X. Although the constraints from BBN, CMB and low-energy experiments set the X-mediated SB-electron scattering cross section to be 10-35 cm2, the MeV scale DM with a resonance enhanced dark annihilation today can still provide enough boosted SB and induce the XENON1T keV excess. The relic density of SB is significantly reduced by the s-wave process of SB SB X X which is allowed by the constraints from CMB and 21-cm absorption. A very small relic fraction of SB is compatible with the stringent bounds on un-boosted SB-electron scattering in DM direct detection and the SA-electron scattering is also allowed.