The $\gamma\pi\to\pi\pi$ anomaly from lattice QCD and dispersion relations

TL;DR

This paper develops a formalism combining dispersion relations and lattice QCD data to accurately extract the $ ho$ meson coupling and the chiral anomaly $F_{3 extpi}$, advancing understanding of meson interactions from first principles.

Contribution

It introduces a novel method to determine the $ ho$ meson radiative coupling and the chiral anomaly $F_{3 extpi}$ from lattice QCD calculations at unphysical pion masses.

Findings

Extracted $F_{3 extpi}$ as 38(16)(11) GeV$^{-3}$, consistent with chiral predictions.

Demonstrated the formalism's ability to extrapolate lattice data to physical pion masses.

Provided a first lattice-based estimate of the $ ho$ meson radiative coupling.

Abstract

We propose a formalism to extract the $\gamma\pi\to\pi\pi$ chiral anomaly $F_{3\pi}$ from calculations in lattice QCD performed at larger-than-physical pion masses. To this end, we start from a dispersive representation of the $\gamma^{(*)}\pi\to\pi\pi$ amplitude, whose main quark-mass dependence arises from the $\pi\pi$ scattering phase shift and can be derived from chiral perturbation theory via the inverse-amplitude method. With parameters constrained by lattice calculations of the $P$-wave phase shift, we use this combination of dispersion relations and effective field theory to extrapolate two recent $\gamma^{(*)}\pi\to\pi\pi$ calculations in lattice QCD to the physical point. Our formalism allows us to extract the radiative coupling of the $\rho(770)$ meson and, for the first time, the chiral anomaly $F_{3\pi}=38(16)(11)\,\text{GeV}^{-3}$. The result is consistent with the chiral prediction albeit within large uncertainties, which will improve in accordance with progress in future lattice-QCD computations.