Theory of 2D superconductor with broken inversion symmetry

Abstract

A detailed theory of a phase diagram of a 2D surface superconductor in a parallel magnetic field is presented. A spin-orbital interaction of the Rashba type is known to produce at a high magnetic field h (and in the absence of impurities) an inhomogeneous superconductive phase similar to the Larkin-Ovchinnikov-Fulde-Ferrel (LOFF) state with an order parameter (r) (Qr). We consider the case of a strong Rashba interaction with the spin-orbital splitting much larger than the superconductive gap , and show that at low temperatures T≤ 0.4 Tc0 the LOFF-type state is separated from the usual homogeneous state by a first-order phase transition line. At higher temperatures another inhomogeneous state with (r) (i Qr) intervenes between the uniform BCS state and the LOFF-like state at gμB h ≈ 1.5 Tc0. The modulation vector Q in both phases is of the order of gμB h/vF. The superfluid density nsyy vanishes in the region around the second-order transition line between the BCS state and the new ``helical'' state. Non-magnetic impurities suppress both inhomogeneous states, and eliminate them completely at Tc0τ ≤ 0.11. However, once an account is made of the next-order term over the small parameter α/vF 1, a relatively long-wave helical modulation with Q gμB hα/vF2 is found to develop from the BCS state. This long-wave modulation is stable with respect to disorder. In addition, we predict that unusual vortex defects with a continuous core exist near the phase boundary between the helical and the LOFF-like states. In particular, in the LOFF-like state these defects may carry a half-integer flux.

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