Stablehc/evortices in a gauge theory of superconductivity in strongly correlated systems

Abstract

A phenomenological model F of the superconducting phase of electronic systems with strong short-range repulsive interactions is studied. Fluctuations of the connection a of an internal U(1) gauge symmetry suppress local charge fluctuations. Above ${\mathit{H}}_{\mathit{c}1}$, magnetic flux can pierce the superconductor in vortices with flux hc/2e throughout the superconducting phase, but regimes are found in which the lowest-energy configuration has vortices with flux hc/e. Experiments by Little and Parks and others, which examine periodicities as a function of a varying magnetic field, always observe a period in external flux of hc/2e. The low-energy properties of a symplectic large-N expansion of a model of the ${\mathrm{CuO}}_2$ layers of the cuprate superconductors are shown to be well described by F. This analysis and some normal-state properties of the cuprates suggest that hc/e vortices should be stable at the lowest dopings away from the insulating state at which superconductivity first occurs, unless the superconductor-normal transition is strongly first order.