Topological Defects in Systems with Two Competing Order Parameters: Application to Superconductors with Charge- and Spin-Density Waves

Abstract

On the basis of coupled Ginzburg--Landau equations we study nonhomogeneous states in systems with two order parameters~(OP). Superconductors with superconducting OP~, and charge- or spin-density wave (CDW or SDW) with amplitude~W are examples of such systems. When one of OP, say~, has a form of a topological defect, like, e.g., vortex or domain wall between the domains with the phases~0 and~π, the other OP~W is determined by the Gross--Pitaevskii equation and is localized at the center of the defect. We consider in detail the domain wall defect for~ and show that the shape of the associated solution for~W depends on temperature and doping (or on the curvature of the Fermi surface)~μ. It turns out that, provided temperature or doping level are close to some discrete values~Tn and~μn, the spacial dependence of the function~W(x) is determined by the form of the eigenfunctions of the linearized Gross--Pitaevskii equation. The spacial dependence of~W0 corresponding to the ground state has the form of a soliton, while other possible solutions~Wn(x) have nodes. Inverse situation~when~W(x) has the form of a topological defect and~(x) is localized at the center of this defect is also possible. In particular, we predict a surface or interfacial superconductivity in a system where a superconductor is in contact with a material that suppresses~W. This superconductivity should have rather unusual temperature dependence existing only in certain intervals of temperature. Possible experimental realizations of such non-homogeneous states of OPs are discussed.