What question did this study set out to answer?

This research aims to compute the one-loop beta-function coefficient in a non-Hermitian gauge theory.

March 16, 2026Open Access

Universal One-Loop Coefficient in GL(k,C) Non-Hermitian Gauge Theory

Key Points

This research aims to compute the one-loop beta-function coefficient in a non-Hermitian gauge theory.
Computed the one-loop beta-function coefficient for GL(k,C) gauge theory.
Analyzed contributions from the Faddeev-Popov ghost and cross-heat-kernel trace.
Derived closed-form expressions for critical mixing parameters and explored wavefunction renormalization.
The one-loop beta-function coefficient is universally -2/11 for k >= 2.
Faddeev-Popov ghost contributions vanish completely.
The biorthogonal wavefunction renormalization product is strictly real and positive within the asymptotically free regime.

Abstract

This manuscript computes the one-loop beta-function coefficient for a GL (k, C) gauge theory deformed by a non-Hermitian mixing parameter. We demonstrate that the Faddeev-Popov ghost contribution vanishes exactly, and a remarkable cancellation in the cross-heat-kernel trace yields a purely universal, rank-independent coefficient C₁ = -2/11 for all k >= 2. Consequently, we derive the exact closed-form expression for the critical mixing parameter, below which asymptotic freedom is robustly preserved. Furthermore, we prove that the biorthogonal wavefunction renormalisation product remains strictly real and positive within this asymptotically free regime, guaranteeing the stability of the conserved information charge under renormalization-group flow. These results establish the ultraviolet consistency of non-Hermitian gauge theories with mixing.

Universal One-Loop Coefficient in GL(k,C) Non-Hermitian Gauge Theory

Key Points

Abstract

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