Universal observable as a signal of chiral anomaly in lattice Weyl fermions

Abstract

The Adler-Bell-Jackiw chiral anomaly is shown to retain its Lorentz-invariant form, ∂μ Jμ5 E · B, in lattice Weyl systems beyond moderate magnetic fields, where neither Lorentz nor rotational symmetry is present. We show that the longitudinal and Hall magnetoconductivities factorize into a product of a universal part, governed by the chiral anomaly, and a non-universal part that depends on the density of states at the Fermi level. A rotationally invariant observable = σ (cV/T)2 is introduced as a robust signature of the anomaly, where σ denotes the Euclidean norm of the longitudinal and Hall conductivities and cV is the specific heat density. This quantity follows a universal B2 dependence and scales as ||, with being the angle between E and B. Through analytical derivation and full numerical simulation, we establish that remains universal independent of system parameters and of the orientation of the magnetic or electric field for fixed . The emergent SO(3) symmetry in persists despite the absence of isotropy in both the microscopic model and the low-energy effective theory.