Scalar dark matter interpretation of the DAMPE data with U(1) gauge interactions

Abstract

Recently, DAMPE experiment released the new measurement of the total cosmic e+e- flux between 25 GeV and 4.6 TeV which indicates a spectral softening at around 0.9 TeV and a tentative peak at around 1.4 TeV. We utilize the scalar dark matter (DM) annihilation scenario to explain the DAMPE peak by extending GSM SU(3)C × SU(2)L × U(1)Y with additional U(1) gauge symmetries while keeping anomaly free to generate Z Z ^, where , Z, () denote the scalar DM, the new gauge boson and ()=e,μ,τ, respectively, with m mZ 2 × 1.5 (TeV). We first illustrate that the minimal framework GSM × U(1)Y with the above mass choices can explain the DAMPE excess but has been excluded by LHC constraints from the Z searches. Then we study a non-minimal framework GSM × U(1)Y × U(1)Y in which U(1)Y mixes with U(1)Y. We show that such a framework can interpret the DAMPE data while passing other constraints including the DM relic abundance, DM direct detection and collider bounds. We also investigate the predicted e+e- spectrum in this framework and find that the mass splitting m = m - mZ' should be less than about 17 GeV to produce the peak-like structure.