Sub-Dominant Pairing Channels in Unconventional Superconductors: Ginzburg-Landau Theory

TL;DR

This paper develops a Ginzburg-Landau theory for unconventional superconductors with multiple pairing channels, revealing complex vortex structures, phase transitions, and the effects of strong coupling and magnetic fields on sub-dominant order parameters.

Contribution

It introduces a comprehensive Ginzburg-Landau framework for sub-dominant pairing channels in unconventional superconductors, analyzing vortex structures and phase transitions.

Findings

Vortex structures differ above and below T_{DS}.

A second order phase transition occurs at T_{DD'}.

Sub-dominant phases can be induced or suppressed by vortices and magnetic fields.

Abstract

A Ginzburg-Landau theory is developed for unconventional superconductors with the three relevant singlet pairing channels. Various consequences of the sub-dominant channels (i.e., s- and d_{xy}-channels) are examined in detail. (1) In the case of a d_{x^2-y^2}+is-wave superconductor, The structure of a single vortex above and below T_{DS} is four-fold and two-fold symmetric, respectively. (2) In the case of a d_{x^2-y^2}+id_{xy}-wave superconductor, there is also a second order zero-field phase transition from the pure d_{x^2-y^2}-phase to the Time-reversal-symmetry-breaking d_{x^2-y^2}+id_{xy}-wave phase at the temperature T_{DD'}. But the subdominant phase can (not) be induced by vortices above T_{DD'}. Below the time-reversal- symmetry-breaking transition, the sub-dominant phase in the mixed state is nontrivial: it survives at low fields, but may disappear above a field (increasing with decreasing temperature) presumably via a first-order transition. (3)By including the strong coupling effects, a time-reversal-symmetry -breaking coupling term between the d_{x^2-y^2}- and d_{xy}-waves is found to have significant effects on the low temperature behavior of d_{x^2-y^2}+id_{xy} superconductors. In a magnetic field, a d_{x^2-y^2}+id_{xy} state is always established, but the field-dependence of d_{xy}-amplitude above T_{DD'} is different from that below T_{DD'}. Above but not very close to T_{DD'}, the induced minimum gap Delta_0 proportional to B/(T-T_{DD'}).