Abstract
We study the effects of failure to equilibrate the squared topological charge $Q^2$ on lattice calculations of pseudoscalar masses and decay constants. The analysis is based on chiral perturbation theory calculations of the dependence of these quantities on the QCD vacuum angle $\theta$. For the light-light partially quenched case, we rederive the known chiral perturbation theory results of Aoki and Fukaya, but using the nonperturbatively-valid chiral theory worked out by Golterman, Sharpe and Singleton, and by Sharpe and Shoresh. We then extend these calculations to heavy-light mesons. Results when staggered taste-violations are important are also presented. The derived $Q^2$ dependence is compared to that of simulations using the MILC collaboration's ensembles of lattices with four flavors of HISQ dynamical quarks. We find agreement, albeit with large statistical errors. These results can be used to correct for the leading effects of unequilibrated $Q^2$, or to make estimates of the systematic error coming from the failure to equilibrate $Q^2$. In an appendix, we show that the partially quenched chiral theory may be extended beyond a lower bound on valence masses discovered by Sharpe and Shoresh. Subtleties occurring when a sea-quark mass vanishes are discussed in another appendix.
Highlights
In continuum QCD the topological charge Q cannot change in a continuous evolution of the gluon fields
We expect that lattice QCD simulations using approximately continuous evolution algorithms should see very slow evolution of the topological charge, since changing the topological charge involves a tunneling where some of the plaquettes or other loops in the gauge action pass through large values
Since the rate at which the topological charge Q changes in a lattice simulation falls off quickly as the lattice spacing decreases, modern QCD simulations are reaching a regime where the distribution of Q cannot be accurately sampled in a simulation with practical length
Summary
Physics Department, University of Arizona, Tucson, Arizona 85721, USA (Received 25 July 2017; published 2 April 2018). For the light-light partially quenched case, we rederive the known chiral perturbation theory results of Aoki and Fukaya, but using the nonperturbatively valid chiral theory worked out by Golterman, Sharpe and Singleton, and by Sharpe and Shoresh. We extend these calculations to heavy-light mesons. These results can be used to correct for the leading effects of unequilibrated Q2, or to make estimates of the systematic error coming from the failure to equilibrate Q2. Subtleties occurring when a sea-quark mass vanishes are discussed in another appendix
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