Spectral Geometry and the One-Loop QED β-Function on S3 × S1

Abstract

We compute the one-loop QED β-function coefficient directly from heat kernel data of the twisted Spinc Dirac operator on S3 × S1. Using ζ-function regularization, the logarithmic scale dependence is encoded in the a4 coefficient of the spectral expansion. The Fμ Fμ term in a4 yields exactly β(e) = e3/(12π2), independent of r, L, or background, verifying spectral RG flow without flat-space propagators. The result is independent of the radii of S3 and S1 and of the choice of gauge background, providing a parameter-free consistency check that spectral data on compact manifolds encode renormalization group information. Beyond a mere verification of the coupling flow, this result serves as a non-trivial consistency check of the Spectral Action Principle in a curved background. It demonstrates that universal quantum corrections can be extracted purely from geometric spectral invariants, distinguishing this geometric spectral derivation from momentum-space propagator methods.

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