Emergence of the $\rho$ resonance from the HAL QCD potential in lattice QCD

TL;DR

This study uses lattice QCD with the HAL QCD method to analyze the $ ho$ meson resonance, successfully extracting the potential and resonance parameters, and demonstrating the feasibility of advanced techniques for all-to-all propagator calculations.

Contribution

First determination of the non-local $I=1$ $ ho$ meson potential at N$^2$LO in lattice QCD, enabling more precise resonance analysis.

Findings

The $ ho$ meson mass agrees with literature.

The coupling $g_{ ho o ho o ho}$ is larger than expected.

All-to-all propagators can be accurately obtained with combined techniques.

Abstract

We investigate the $I=1$ $\pi \pi$ interaction using the HAL QCD method in lattice QCD. We employ the (2+1)-flavor gauge configurations on $32^3 \times 64$ lattice at the lattice spacing $a \approx 0.0907$ fm and $m_{\pi} \approx 411$ MeV, in which the $\rho$ meson appears as a resonance state. We find that all-to-all propagators necessary in this calculation can be obtained with reasonable precision by a combination of three techniques, the one-end trick, the sequential propagator, and the covariant approximation averaging (CAA). The non-local $I=1$ $\pi \pi$ potential is determined at the next-to-next-to-leading order (N$^2$LO) of the derivative expansion for the first time, and the resonance parameters of the $\rho$ meson are extracted. The obtained $\rho$ meson mass is found to be consistent with the value in the literature, while the value of the coupling $g_{\rho \pi \pi}$ turns out to be somewhat larger. The latter observation is most likely attributed to the lack of low-energy information in our lattice setup with the center-of-mass frame. Such a limitation may appear in other P-wave resonant systems and we discuss possible improvement in future. With this caution in mind, we positively conclude that we can reasonably extract the N$^2$LO potential and resonance parameters even in the system requiring the all-to-all propagators in the HAL QCD method, which opens up new possibilities for the study of resonances in lattice QCD.