The invariant factor of the chiral determinant

TL;DR

This paper reveals that the non-anomalous part of the chiral determinant can be expressed as the square root of a local covariant operator's determinant, simplifying the analysis of chiral anomalies.

Contribution

It introduces a method to isolate the chiral invariant factor of the determinant as a square root of a local operator, bypassing integrability issues.

Findings

The chiral invariant factor is the square root of a local covariant operator's determinant.

The method reproduces known results in two-dimensional effective actions.

The approach simplifies the analysis of chiral determinants and anomalies.

Abstract

The coupling of spin 0 and spin 1 external fields to Dirac fermions defines a theory which displays gauge chiral symmetry. Quantum mechanically, functional integration of the fermions yields the determinant of the Dirac operator, known as the chiral determinant. Its modulus is chiral invariant but not so its phase, which carries the chiral anomaly through the Wess-Zumino-Witten term. Here we find the remarkable result that, upon removal from the chiral determinant of this known anomalous part, the remaining chiral invariant factor is just the square root of the determinant of a local covariant operator of the Klein-Gordon type. This procedure bypasses the integrability obstruction allowing to write down a functional that correctly reproduces both the modulus and the phase of the chiral determinant. The technique is illustrated by computing the effective action in two dimensions at leading order in the derivative expansion. The results previously obtained by indirect methods are indeed reproduced.