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We demonstrate that the O(a) taste mixing exhibited in standard textbook presentations of staggered quarks is an artifact of the particular definition of the flavor fields in those presentations, and has nothing to do with the underlying precision of staggered-quark actions, despite continuing comments to the contrary in the current literature. To illustrate this point we introduce a new coordinate-space definition of the flavor fields that suppresses the O(a) term by two additional powers of a. In fact there are no errors at all from this mechanism. The only source of taste mixing comes from the exchange of highly-virtual gluons and enters in O(a^2). We review the idiosyncrasies of Symanzik improvement for naive/staggerd-quark actions, and show how these results follow from that program.
We explore sea quark effects in the light hadron mass spectrum in a simulation of two-flavor QCD using the nonperturbatively O(a)-improved Wilson fermion action. In order to identify finite-size effects, light meson masses are measured on 12^3x48, 16
We present the results of our perturbative calculations of the static quark potential, small Wilson loops, the static quark self energy, and the mean link in Landau gauge. These calculations are done for the one loop Symanzik improved gluon action, and the improved staggered quark action.
We study hadron properties near the deconfining transition in the quenched lattice QCD simulation. This paper focuses on the heavy quarkonium states, such as $J/psi$ meson. In order to treat heavy quarks at $T>0$, we adopt the $O(a)$ improved Wilson
We study the question of whether or not QCD predicts a pentaquark state. We use the improved, fixed point lattice QCD action which has very little sensitivity to the lattice spacing and also allows us to reach light quark masses. The analysis was per
We compute the Landau gauge quark propagator from lattice QCD with two flavors of dynamical O(a)-improved Wilson fermions. The calculation is carried out with lattice spacings ranging from 0.06 fm to 0.08 fm, with quark masses corresponding to pion m