Classifying Causal Nonlinear Electrodynamics via -Parity and Irrelevant Deformations

Abstract

We investigate the classification of self-dual nonlinear electrodynamic (NED) theories based on their analyticity properties, which are directly linked to invariance under a discrete -parity transformation. This classification is expressed through the structure of the irrelevant TT-like deformations that generate the theories from a Maxwell seed. Using both closed-form and perturbative methods within the Courant-Hilbert (CH) and Russo-Townsend auxiliary field formalisms, we demonstrate a precise correspondence: -parity-invariant, analytic theories are generated by irrelevant deformations built from integer powers of the energy-momentum tensor scalars, Oλ Σ Cm (TμTμ)1-m(TμμT)m. Conversely, -parity-violating, non-analytic theories require deformations involving both integer and half-integer powers, Oλ Σ Cm (TμTμ)1-m/2(TμμT)m/2. We prove this result in generality via a perturbative CH framework, showing that -parity invariance imposes specific constraints on the expansion coefficients of the CH function (τ) which, in turn, force all half-integer powers in the deformation to vanish. The classification is explicitly verified for known closed-form theories: the analytic generalized Born-Infeld model and the non-analytic examples of the q=3/4-deformed and "no τ-maximum" theories. Furthermore, we show how the -parity transformation is consistently generalized in the presence of a marginal root-TT coupling γ, and we derive the corresponding marginal and irrelevant flow equations for the studied theories.