Anatomy of the $Ï$ resonance from lattice QCD at the physical point
arXiv:1507.02541 · doi:10.1088/1674-1137/42/6/063102
Abstract
We propose a strategy to access the $q\bar{q}$ component of the $Ï$ resonance in lattice QCD. Through a mixed action formalism (overlap valence on domain wall sea), the energy of the $q\bar{q}$ component is derived at different valence quark masses, and shows a linear dependence on $m_Ï^2$. The slope is determined to be $c_1=0.505(3)\,{\rm GeV}^{-1}$, from which the valence $ÏÏ$ sigma term is extracted to be $Ï_{ÏÏ}^{(\rm val)}=9.82(6)$ MeV using the Feynman-Hellman theorem. At the physical pion mass, the mass of the $q\bar{q}$ component is interpolated to be $m_Ï=775.9\pm 6.0\pm 1.8$ MeV, which is close to the $Ï$ resonance mass. We also obtain the leptonic decay constant of the $q\bar{q}$ component to be $f_{Ï^-}=208.5\pm 5.5\pm 0.9$ MeV, which can be compared with the experimental value $f_Ï^{\rm exp}\approx 221$ MeV through the relation $f_Ï^{\rm exp}=\sqrt{Z_Ï}f_{Ï^\pm} $ with $Z_Ï\approx 1.13$ being the on-shell wavefunction renormalization of $Ï$ owing to the $Ï-Ï$ interaction. We emphasize that $m_Ï$ and $f_Ï$ of the $q\bar{q}$ component, which are obtained for the first time from QCD, can be taken as the input parameters of $Ï$ in effective field theory studies where $Ï$ acts as a fundamental degree of freedom.
7 pages, 4 figures. Considerably modified, more discussions, matching to the published version