Dark Parton Shower Effects for Cosmic Ray Boosted Dark Matter

Abstract

We investigate the dark parton shower effects in the direct detection of cosmic-ray boosted dark matter (CRDM), focusing on a dark photon-mediated model with fermionic dark matter-electron interactions. Utilizing a Monte Carlo framework to incorporate the Sudakov form factors and kinematic dipole recoil schemes, we simulate the CRDM energy spectrum evolution under the dark sector splitting. Our results reveal a significant energy-dependent modification of the CRDM flux. For a 1 keV dark matter (DM) mass and a coupling of gD=3, the CRDM flux can be enhanced by a factor up to 1.12 in the O(10-2 1) MeV energy range for 2m mA 10-2 MeV, while it is suppressed by more than 50\% at energy around 100 MeV for mA 10-3 MeV. We then translate these effects into the experimental sensitivities for PandaX-4T, Super-Kamiokande, and JUNO. At mA = 10-3 MeV and gD=3, the bounds on the kinetic mixing parameter ε2 are relaxed by factors of 1.02, 1.6 and 1.4, respectively. Finally, we demonstrate that the parameter space considered is consistent with those astrophysical constraints on dark matter self-interactions from observations of the Bullet Cluster.