Two-pole nature of the $\Lambda(1405)$ from lattice QCD

TL;DR

This study uses lattice QCD to analyze the $ar{K}N$ and $ ext{pi} ext{Sigma}$ scattering amplitudes near 1405 MeV, providing evidence for a two-pole structure of the $ ext{Lambda}(1405)$ resonance.

Contribution

First lattice QCD computation of coupled channel scattering amplitudes near 1405 MeV supporting the two-pole nature of $ ext{Lambda}(1405)$.

Findings

Supports the two-pole structure of $ ext{Lambda}(1405)$

Identifies a virtual bound state below $ ext{pi} ext{Sigma}$ threshold

Uses multiple parametrizations of the $K$-matrix

Abstract

This letter presents the first lattice QCD computation of the coupled channel $\pi\Sigma-\bar{K}N$ scattering amplitudes at energies near $1405\,{\rm MeV}$. These amplitudes contain the resonance $\Lambda(1405)$ with strangeness $S=-1$ and isospin, spin, and parity quantum numbers $I(J^P)=0(1/2^-)$. However, whether there is a single resonance or two nearby resonance poles in this region is controversial theoretically and experimentally. Using single-baryon and meson-baryon operators to extract the finite-volume stationary-state energies to obtain the scattering amplitudes at slightly unphysical quark masses corresponding to $m_\pi\approx200$ MeV and $m_K\approx487$ MeV, this study finds the amplitudes exhibit a virtual bound state below the $\pi\Sigma$ threshold in addition to the established resonance pole just below the $\bar{K}N$ threshold. Several parametrizations of the two-channel $K$-matrix are employed to fit the lattice QCD results, all of which support the two-pole picture suggested by $SU(3)$ chiral symmetry and unitarity.