The Meissner effect and the vortex structure in stacked junctions and layered superconductors: Exact analytical results

Abstract

We present an exact mathematical description of the Meissner effect and of the vortex state in periodic thin-layer superconductor/insulator structures with an arbitrary number of identical junctions N-1 (N is the number of superconducting layers) in the presence of a static parallel external field H. Based on an analytical analysis of the coupled static sine-Gordon (SG) equations for the phase differences, we obtain a complete classification of all possible types of physical solutions. We prove that at H>0 these equations admit only Meissner solutions and topological ''vortex-plane'' solutions. Both the types of solutions are characterized by [N/2] Josephson lengths. We derive an explicit analytical expression for the superheating field of the Meissner state, Hs, as a function of N and show that Hs simultaneously determines the penetration field for the vortex planes. Thermodynamically stable ''vortex-plane'' solutions represent coherent chains of Josephson vortices (one vortex per each insulating layer in a chain). Being a natural generalization of ordinary Josephson vortices in a single junction, the vortex-plane solutions inherit such properties of the former as periodicity along the layers and the overlapping of states with different topological numbers. We obtain exact analytical expressions for the self-energy of a vortex plane and for the lower critical field Hc1. In contrast to a prevailing view, the coupled SG equations do not possess any single-vortex solutions for H>0. The general consideration is illustrated by two exactly-solvable examples (N=2,3). Experimental implications of the results are discussed.

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