Spacetime torsion fixes the mass and spin of gravitationally produced dark matter

Abstract

The gravitational production of dark matter from stochastic gravitational waves requires the produced fermion to acquire a mass by unspecified late-time physics. We show that this mass is supplied by spacetime torsion alone -- no Higgs sector and no free mass parameter. In the Quadratic Spinor Lagrangian formulation of general relativity, extended to Einstein--Cartan, a cosmological spinor condensate generates a vectorial trace torsion Kχ/χ; an explicit Clifford reduction confers on the produced spin-1/2 fermion a pure Dirac mass M eff=(1/6)\,|χ/χ|, with no pseudoscalar or cross terms, locked to the Hubble rate at production, M eff(cχ/6)H*. The relic abundance is then a one-parameter prediction, Ωh2 H*5/2, and the spin is fixed: the same framework admits no propagating spin-3/2 mode, so the composite spin-1/2 Dirac fermion is its unique dark-matter candidate.