Enhanced chiral edge currents and orbital magnetic moment in chiral d-wave superconductors from mesoscopic finite-size effects

Abstract

Chiral superconductors spontaneously break time-reversal symmetry and host topologically protected edge modes, supposedly generating chiral edge currents which are typically taken as a characteristic fingerprint of chiral superconductivity. However, recent studies have shown that the total edge current in two dimensions (2D) often vanishes for all chiral superconductors except for chiral p-wave, especially at low temperatures, thus severely impeding potential experimental verification and characterization of these superconductors. In this work, we use quasiclassical theory of superconductivity to study mesoscopic disc-schaped chiral d-wave superconductors. We find that mesoscopic finite-size effects cause a dramatic enhancement of the total charge current and orbital magnetic moment (OMM), even at low temperatures. We study how these quantities scale with temperature, spontaneous Meissner screening, and system radius R ∈ [5,200]0 with superconducting coherence length 0. We find a general 1/R scaling in the total charge current and OMM for sufficiently large systems, but this breaks down in small systems, instead producing a local maximum at R ≈ 10--200 due to mesoscopic finite-size effects. These effects also cause a spontaneous charge-current reversal opposite to the chirality below R < 100. Our work highlights mesoscopic systems as a route to experimentally verify chiral d-wave superconductivity, measurable with magnetometry.