Canonical seesaw implication for two-component dark matter

Abstract

We show that the canonical seesaw mechanism implemented by the U(1)B-L gauge symmetry provides two-component dark matter naturally. The seesaw scale that breaks B-L defines a residual gauge symmetry to be Z6=Z2 Z3, where Z2 leads to the usual matter parity, while Z3 is newly recognized, transforming quark fields nontrivially. The dark matter components -- that transform nontrivially under the matter parity and Z3, respectively -- can gain arbitrary masses, despite the fact that the Z3 dark matter may be heavier than the light quarks u,d. This dark matter setup can address the XENON1T anomaly recently observed and other observables, given that the dark matter masses are nearly degenerate, heavier than the electron and the B-L gauge boson Z', as well as the fast-moving Z3 dark matter has a large B-L charge, while the Z' is viably below the beam dump experiment sensitive regime.