Critical temperature for first-order phase transitions in confined systems

Abstract

We consider the Euclidean D-dimensional -λ |φ |4+η |φ |6 (λ ,η >0 ) model with d (d≤ D) compactified dimensions. Introducing temperature by means of the Ginzburg--Landau prescription in the mass term of the Hamiltonian, this model can be interpreted as describing a first-order phase transition for a system in a region of the D-dimensional space, limited by d pairs of parallel planes, orthogonal to the coordinates axis x1, x2, ..., xd. The planes in each pair are separated by distances L1, L2, ..., Ld. We obtain an expression for the transition temperature as a function of the size of the system, % Tc(\Li\), i=1, 2, ..., d. For D=3 we particularize this formula, taking L1=L2=... =Ld=L for the physically interesting cases d=1 (a film), d=2 (an infinitely long wire having a square cross-section), and for d=3 (a cube). For completeness, the corresponding formulas for second-order transitions are also presented. Comparison with experimental data for superconducting films and wires shows qualitative agreement with our theoretical expressions