Abstract In the presence of spacetime torsion, the momentum components do not commute; therefore, in quantum field theory, summation over the momentum eigenvalues will replace integration over the momentum.
In the Einstein--Cartan theory of gravity, in which torsion is coupled to spin, the separation between the eigenvalues increases with the magnitude of the momentum.
Consequently, this replacement regularizes divergent integrals in Feynman diagrams with loops by turning them into convergent sums.
In this article, we apply torsional regularization to the self-energy of a charged lepton in quantum electrodynamics.
We show that torsion eliminates the ultraviolet divergence of the standard self-energy. 
We also show that the infrared divergence is absent.
In the end, we calculate the finite bare masses of the electron, muon, and tau lepton: $0.4329\,\mbox{MeV}$, $90.95\,\mbox{MeV}$, and $1543\,\mbox{MeV}$, respectively.
These values constitute about $85\%$ of the observed, re-normalized masses.