Preliminary lattice study of the I=1 $K \bar{K}$ scattering length
Authors
Ziwen Fu
Categories
Abstract
The s-wave kaon-antikaon ($K \bar{K}$) elastic scattering length is investigated by lattice simulation using pion masses $m_π= 330 - 466$ MeV. Through moving wall sources without gauge fixing, we calculate $K \bar{K}$ four-point correlation functions for isospin I=1 channel in the "Asqtad" improved staggered fermion formulation, and observe a clear signal of attraction, which is consistent with other pioneering lattice studies on $K \bar{K}$ potential. Extrapolating $K \bar{K}$ scattering length to the physical point, we obtain $m_{K} a^{I=1}_{K\bar{K}} = 0.211(33)$. These simulations are performed with MILC gauge configurations at lattice spacing $a \approx 0.15$ fm.
Preliminary lattice study of the I=1 $K \bar{K}$ scattering length
Categories
Abstract
The s-wave kaon-antikaon ($K \bar{K}$) elastic scattering length is investigated by lattice simulation using pion masses $m_π= 330 - 466$ MeV. Through moving wall sources without gauge fixing, we calculate $K \bar{K}$ four-point correlation functions for isospin I=1 channel in the "Asqtad" improved staggered fermion formulation, and observe a clear signal of attraction, which is consistent with other pioneering lattice studies on $K \bar{K}$ potential. Extrapolating $K \bar{K}$ scattering length to the physical point, we obtain $m_{K} a^{I=1}_{K\bar{K}} = 0.211(33)$. These simulations are performed with MILC gauge configurations at lattice spacing $a \approx 0.15$ fm.
Authors
Ziwen Fu
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