Stability of Mixed-Symmetry Superconducting States with Broken Time-Reversal Symmetry against Lattice Distortions

Abstract

We examine the stability of mixed-symmetry superconducting states with broken time-reversal symmetry in spatial-symmetry-broken systems, including chiral states, on the basis of the free-energy functional derived in the weak-coupling theory. We consider a generic a1 + i a2 wave state, with a1 and a2 being different symmetry indices such as (a1,a2) = (d,s), (px,py), and (d,d').The time-reversal symmetry of the mixed-symmetry state with the a1- and a2-wave components is broken when the phases of these components differ, and such a state is called the time-reversal-symmetry breaking (TRSB) state. However, their phases are equated by Cooper-pair scattering between these components if it occurs; i.e., when the off-diagonal elements Sa1 a2 = Sa2 a1 of the scattering matrix are nonzero, they destabilize the TRSB state. Hence, it has often been believed that the TRSB state is stable only in systems with a spatial symmetry that guarantees Sa1 a2=0. We note that, contrary to this belief, the TRSB state can remain stable in systems without the spatial symmetry when the relative phase shifts so that Sa1 a2 = 0 is restored, which results in a distorted TRSB (a1 + a2) + i a2 wave state. Here, note that the restoration of Sa1 a2 = 0 does not imply that the symmetry of the quasi-particle energy Ek is recovered. This study shows that such stabilization of the TRSB state occurs when the distortion is sufficiently small and a1 a2 is sufficiently large, where a is the amplitude of the a-wave component in the TRSB state in the absence of the distortion. We clarify the manner in which the shift in the relative phase eliminates Sa1 a2 and prove that such a state yields a free-energy minimum. We also propose a formula for the upper bound of the degree of lattice distortion, below which the TRSB state can be stable.