Imaging the paramagnetic nonlinear Meissner effect in nodal gap superconductor

TL;DR

This study visualizes the anisotropic paramagnetic nonlinear Meissner effect in nodal gap superconductors, revealing surface Andreev bound states' response to RF fields through combined experimental imaging and theoretical modeling.

Contribution

It introduces a systematic imaging technique and a theoretical model to understand the surface paramagnetic response in nodal gap superconductors, highlighting the role of Andreev bound states.

Findings

Surface paramagnetic response dominates at low temperatures.

Anisotropic nonlinear response depends on current direction and RF power.

Theoretical model aligns well with experimental observations.

Abstract

Boundary surfaces of nodal gap superconductors can host Andreev bound states (ABS) which develop a paramagnetic response under external RF field in contrast to the bulk diamagnetic response of the bulk superconductor. At low temperature this surface paramagnetic response dominates and enhances the nonlinear RF response of the sample. With a recently developed photoresponse imaging technique, the anisotropy of this "paramagnetic" nonlinear Meissner response, and its current direction (angular) and RF power dependence has been systematically studied. A theoretical model describing the current flow in the surface paramagnetic Andreev bound state, the bulk diamagnetic Meissner state, and their response to optical illumination is proposed and it shows good agreement with the experimental results.