Finite-size scaling around the critical point in the heavy quark region of QCD

Abstract

Finite-size scaling is investigated in detail around the critical point in the heavy-quark region of nonzero temperature QCD. Numerical simulations are performed with large spatial volumes up to the aspect ratio Ns/Nt=12 at a fixed lattice spacing with Nt=4. We show that the Binder cumulant and the distribution function of the Polyakov loop follow the finite-size scaling in the Z(2) universality class for large spatial volumes with Ns/Nt 9, while, for Ns/Nt 8, the Binder cumulant becomes inconsistent with the Z(2) scaling. To realize the large-volume simulations in the heavy-quark region, we adopt the hopping parameter expansion for the quark determinant: We generate gauge configurations using the leading order action including the Polyakov loop term for Nt=4, and incorporate the next-to-leading order effects in the measurements by the multipoint reweighting method. We find that the use of the leading-order configurations is crucially effective in suppressing the overlapping problem in the reweighting and thus reducing the statistical errors.