Lattice QCD with two dynamical flavors of domain wall quarks

TL;DR

This study demonstrates the feasibility of large-scale two-flavor QCD simulations using domain wall fermions, providing insights into hadron spectrum, decay constants, and CP violation parameters with improved chiral symmetry.

Contribution

First large-scale dynamical DWF QCD simulation analyzing hadron spectrum, decay constants, and B_K parameter with non-degenerate quark masses.

Findings

B_K(MS-bar, 2 GeV) = 0.495(18)

Effective simulation of dynamical DWF on large lattices

Consistent results for hadron spectrum and decay constants

Abstract

We present results from the first large-scale study of two flavor QCD using domain wall fermions (DWF), a chirally symmetric fermion formulation which has proven to be very effective in the quenched approximation. We work on lattices of size 16^3x32, with a lattice cut-off of a^{-1}\approx 1.7 GeV, and dynamical (or sea) quark masses in the range m_{strange}/2 \simle m_{sea} \simle m_{strange}. After discussing the algorithmic and implementation issues involved in simulating dynamical DWF, we report on the low-lying hadron spectrum, decay constants, static quark potential, and the important kaon weak matrix element describing indirect CP violation in the Standard Model, B_K. In the latter case we include the effect of non-degenerate quark masses (m_s \neq m_u = m_d), finding B_K(MS-bar, 2 GeV) = 0.495(18).