Abstract
AbstractWe investigate the HAL QCD potential in $I=1$$\pi \pi$ scattering using the hybrid method for all-to-all propagators, in which a propagator is approximated by low eigenmodes, and the remaining high-eigenmode part is stochastically estimated. To verify the applicability of the hybrid method to systems containing quark creation$/$annihilation contributions such as the $\rho$ meson, we calculate the $I=1$$\pi\pi$ potential with the $(2+1)$-flavor gauge configurations on a $16^3 \times 32$ lattice with lattice spacing $a \approx 0.12$ fm and $(m_{\pi},m_{\rho}) \approx (870, 1230)$ MeV, in which the $\rho$ meson appears as a deeply bound state. While we find that the naive stochastic evaluations for quark creation$/$annihilation contributions lead to extremely large statistical fluctuations, additional noise reduction methods enable us to obtain a sufficiently precise potential, which shows a strong attractive force. We also confirm that the binding energy and $k^3 \cot \delta$ obtained from our potential are roughly consistent with an existing $\rho$ meson bound state, within the large systematic error associated with our calculation, whose possible origin is also discussed.
Highlights
It is revealed that stochastic estimations in the hybrid method for quark creation/annihilation contributions extremely enhance statistical fluctuations of the HAL QCD potential, and we have to take some additional noise reductions to obtain a sufficiently precise potential
(∆t = 0) NBS wave function, conventionally employed in the HAL QCD method, where two sink hadron operators are put on the same time slice
The HAL QCD potential depends on the choice of hadron operators in the definition of the NBS wave function, and we call it “scheme”-dependence of the potential [17, 22]
Summary
One of the most challenging issues in particle and nuclear physics is to understand hadronic resonances in terms of the fundamental theory of quarks and gluons, Quantum Chromodynamics(QCD) To achieve this goal, two methods to study hadron-hadron interactions non-perturbatively in lattice QCD have been employed so far: the Lüscher’s finite volume method [1–3] and the HAL QCD method [4–7]. Wave function calculated in lattice QCD, from which physical observables are extracted afterward This method has a unique advantage for the understanding of hadronic resonances from the first-principle. It is revealed that stochastic estimations in the hybrid method for quark creation/annihilation contributions extremely enhance statistical fluctuations of the HAL QCD potential, and we have to take some additional noise reductions to obtain a sufficiently precise potential.
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