Spontaneously broken translational symmetry at edges of high-temperature superconductors: thermodynamics in magnetic field

Abstract

We investigate equilibrium properties, including structure of the order parameter, superflow patterns, and thermodynamics of low-temperature surface phases of layered dx2-y2-wave superconductors in magnetic field. At zero external magnetic field, time-reversal symmetry and continuous translational symmetry along the edge are broken spontaneously in a second order phase transition at a temperature T*≈ 0.18 Tc, where Tc is the superconducting transition temperature. At the phase transition there is a jump in the specific heat that scales with the ratio between the edge length D and layer area A as (D0/ A) Cd, where Cd is the jump in the specific heat at the d-wave superconducting transition and 0 is the superconducting coherence length. The phase with broken symmetry is characterized by a gauge invariant superfluid momentum ps that forms a non-trivial planar vector field with a chain of sources and sinks along the edges with a period of approximately 120, and saddle point disclinations in the interior. To find out the relative importance of time-reversal and translational symmetry breaking we apply an external field that breaks time-reversal symmetry explicitly. We find that the phase transition into the state with the non-trivial ps vector field keeps its main signatures, and is still of second order. In the external field, the saddle point disclinations are pushed towards the edges, and thereby a chain of edge motifs are formed, where each motif contains a source, a sink, and a saddle point. Due to a competing paramagnetic response at the edges, the phase transition temperature T* is slowly suppressed with increasing magnetic field strength, but the phase with broken symmetry survives into the mixed state.