Abstract
Anisotropic lattice spacings are mandatory to reach the high temperatures where chiral symmetry is restored in the strong coupling limit of lattice QCD. Here, we propose a simple criterion for the nonperturbative renormalisation of the anisotropy coupling in strongly-coupled SU($N$) or U($N$) lattice QCD with massless staggered fermions. We then compute the renormalised anisotropy, and the strong-coupling analogue of Karsch's coefficients (the running anisotropy), for $N=3$. We achieve high precision by combining diagrammatic Monte Carlo and multi-histogram reweighting techniques. We observe that the mean field prediction in the continuous time limit captures the nonperturbative scaling, but receives a large, previously neglected correction on the unit prefactor. Using our nonperturbative prescription in place of the mean field result, we observe large corrections of the same magnitude to the continuous time limit of the static baryon mass, and of the location of the phase boundary associated with chiral symmetry restoration. In particular, the phase boundary, evaluated on different finite lattices, has a dramatically smaller dependence on the lattice time extent. We also estimate, as a byproduct, the pion decay constant and the chiral condensate of massless SU(3) QCD in the strong coupling limit at zero temperature.
Highlights
The sign problem in lattice QCD with staggered fermions at finite density has been solved at strong coupling
In this Letter we present a simple, precise, and nonperturbative method to calibrate the anisotropy coupling in lattice QCD with massless staggered fermions, in the limit of strong gauge coupling
This partition function is a constrained sum over integer occupation numbers of monomers and dimers, nx, kxμ ∈ f0; 1; ...; Ncg, and of oriented baryon links, lxμ ∈ f0; Æ1g, which combine to form oriented baryon loops
Summary
The sign problem in lattice QCD with staggered fermions at finite density has been solved at strong coupling. The physical parameters a and ξ can only be varied implicitly, through independent bare parameters: the bare gauge coupling β and the bare anisotropy coupling γ These bare parameters couple differently to the spatial and temporal plaquettes in the Wilson action of SUðNcÞ or UðNcÞ pure lattice gauge theory in d þ 1 dimensions [3]: Sg β γ. The relation between bare and renormalized anisotropy couplings can only be determined numerically This has been done, for example, in pure gauge theory [3,6], in lattice QCD with staggered fermions [7] or Wilson fermions [8]. In this Letter we present a simple, precise, and nonperturbative method to calibrate the anisotropy coupling in lattice QCD with massless staggered fermions, in the limit of strong gauge coupling
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
