Finite-size corrections to scaling of the magnetization distribution in the 2d XY-model at zero temperature

Abstract

The zero-temperature, classical XY-model on an L × L square-lattice is studied by exploring the distribution L(y) of its centered and normalized magnetization y in the large L limit. An integral representation of the cumulant generating function, known from earlier works, is used for the numerical evaluation of L(y), and the limit distribution L → ∞ (y) = 0(y) is obtained with high precision. The two leading finite-size corrections L (y) -0 (y) ≈ a1(L)\, 1(y) + a2(L)\,2(y) are also extracted both from numerics and from analytic calculations. We find that the amplitude a1(L) scales as (L/L0) /L2 and the shape correction function 1 (y) can be expressed through the low-order derivatives of the limit distribution, 1 (y) = [\,y\, 0 (y) + '0 (y)\,]'. The second finite-size correction has an amplitude a2(L) 1/L2 and one finds that a2\,2(y) a1 \,1(y) already for small system size (L> 10). We illustrate the feasibility of observing the calculated finite-size corrections by performing simulations of the XY-model at low temperatures, including T = 0.