Constraints on the two-pion contribution to hadronic vacuum polarization

TL;DR

This paper investigates how the two-pion contribution to hadronic vacuum polarization, crucial for the muon g-2 anomaly, can vary within phenomenological constraints, highlighting potential modifications detectable by future lattice-QCD studies.

Contribution

It provides a dispersive analysis linking the two-pion contribution to multiple low-energy observables, identifying scenarios for significant variation consistent with phenomenology.

Findings

A ~4% shift in the two-pion contribution is possible without conflicting with existing data.

Inelastic effects and phase shifts are key to understanding the variability of the HVP contribution.

Future lattice-QCD calculations can probe the predicted changes in the pion charge radius and space-like region.

Abstract

At low energies hadronic vacuum polarization (HVP) is strongly dominated by two-pion intermediate states, which are responsible for about $70\%$ of the HVP contribution to the anomalous magnetic moment of the muon, $a_\mu^\text{HVP}$. Lattice-QCD evaluations of the latter indicate that it might be larger than calculated dispersively on the basis of $e^+e^-\to\text{hadrons}$ data, at a level which would contest the long-standing discrepancy with the $a_\mu$ measurement. In this Letter we study to which extent this $2\pi$ contribution can be modified without, at the same time, producing a conflict elsewhere in low-energy hadron phenomenology. To this end we consider a dispersive representation of the $e^+e^- \to 2\pi$ process and study the correlations which thereby emerge between $a_\mu^\text{HVP}$, the hadronic running of the fine-structure constant, the $P$-wave $\pi\pi$ phase shift, and the charge radius of the pion. Inelastic effects play an important role, despite being constrained by the Eidelman-Lukaszuk bound. We identify scenarios in which $a_\mu^\text{HVP}$ can be altered substantially, driven by changes in the phase shift and/or the inelastic contribution, and illustrate the ensuing changes in the $e^+e^-\to 2\pi$ cross section. In the combined scenario, which minimizes the effect in the cross section, a uniform shift around $4\%$ is required. At the same time both the analytic continuation into the space-like region and the pion charge radius are affected at a level that could be probed in future lattice-QCD calculations.