Finite-size scaling behavior in trapped systems

Abstract

Numerical transfer-matrix methods are applied to two-dimensional Ising spin systems, in presence of a confining magnetic field which varies with distance | x| to a "trap center", proportionally to (| x|/)p, p>0. On a strip geometry, the competition between the "trap size" and the strip width, L, is analysed in the context of a generalized finite-size scaling ansatz. In the low-field regime L, we use conformal-invariance concepts in conjunction with a linear-response approach to derive the appropriate (p-dependent) limit of the theory, which agrees very well with numerical results for magnetization profiles. For high fields L, correlation-length scaling data broadly confirms an existing picture of p-dependent characteristic exponents. Standard spin-1/2 and spin-1 Ising systems are considered, as well as the Blume-Capel model.