Full nonperturbative QCD simulations with 2+1 flavors of improved staggered quarks

TL;DR

This paper reports on advanced lattice QCD simulations using improved staggered quarks, achieving controlled extrapolations of low energy QCD observables with multiple quark masses and lattice spacings, impacting phenomenology.

Contribution

It introduces full nonperturbative QCD simulations with 2+1 flavors of improved staggered quarks, detailing the formalism, ensembles, and their applications in phenomenological studies.

Findings

Controlled continuum and chiral extrapolations of QCD observables

Extensive physics results including hadron spectrum and quark masses

Publicly available lattice ensembles used for diverse studies

Abstract

Dramatic progress has been made over the last decade in the numerical study of quantum chromodynamics (QCD) through the use of improved formulations of QCD on the lattice (improved actions), the development of new algorithms and the rapid increase in computing power available to lattice gauge theorists. In this article we describe simulations of full QCD using the improved staggered quark formalism, ``asqtad'' fermions. These simulations were carried out with two degenerate flavors of light quarks (up and down) and with one heavier flavor, the strange quark. Several light quark masses, down to about 3 times the physical light quark mass, and six lattice spacings have been used. These enable controlled continuum and chiral extrapolations of many low energy QCD observables. We review the improved staggered formalism, emphasizing both advantages and drawbacks. In particular, we review the procedure for removing unwanted staggered species in the continuum limit. We then describe the asqtad lattice ensembles created by the MILC Collaboration. All MILC lattice ensembles are publicly available, and they have been used extensively by a number of lattice gauge theory groups. We review physics results obtained with them, and discuss the impact of these results on phenomenology. Topics include the heavy quark potential, spectrum of light hadrons, quark masses, decay constant of light and heavy-light pseudoscalar mesons, semileptonic form factors, nucleon structure, scattering lengths and more. We conclude with a brief look at highly promising future prospects.