FIRST ORDER PHASE TRANSITIONS IN A SOLID WITH FINITE SIZE

Abstract

First order phase transitions are rounded in solids of finite size. It is shown here that the above rounding is monitored by the correlation length ξ_L of the finite system, or equivalently by the so-called mass gap for the quantum Hamiltonian version of the model. Scaling with size is studied as a function of variable boundary conditions for the cylinder geometry (infinite strips with finite width), and a striking crossover is found in the mass gap behavior when the coupling g along the boundary becomes anti-periodic. For g>0, the rounding is exponential with size and an accurate determination of the spontaneous magnetization (order parameter) of the infinite system is obtained from numerical extrapolations.