Exact Three Dimensional Casimir Force Amplitude, C-function and Binder's Cumulant Ratio: Spherical Model Results
Abstract
The three dimensional mean spherical model on a hypercubic lattice with a film geometry L× ∞ 2 under periodic boundary conditions is considered in the presence of an external magnetic field H. The universal Casimir amplitude and the Binder's cumulant ratio B are calculated exactly and found to be =-2ζ (3)/(5π)≈ -0.153051 and B=2π /(5 3[(1+5)/2]). A discussion on the relations between the finite temperature C-function, usually defined for quantum systems, and the excess free energy (due to the finite-size contributions to the free energy of the system) scaling function is presented. It is demonstrated that the C-function of the model equals 4/5 at the bulk critical temperature Tc. It is analytically shown that the excess free energy is a monotonically increasing function of the temperature T and of the magnetic field |H| in the vicinity of Tc. This property is supposed to hold for any classical d-dimensional O(n),n>2, model with a film geometry under periodic boundary conditions when d≤ 3. An analytical evidence is also presented to confirm that the Casimir force in the system is negative both below and in the vicinity of the bulk critical temperature Tc.
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