Proximity and Josephson effects in microstructures based on multiband superconductors

TL;DR

This paper reviews theoretical and experimental research on proximity and Josephson effects in multiband superconductors, highlighting their unique properties and the insights they provide into the symmetry of the order parameter.

Contribution

It provides a comprehensive summary of recent findings on proximity and Josephson effects in multiband superconductors, emphasizing phase-sensitive techniques and their implications.

Findings

Multiband superconductors exhibit distinctive proximity and Josephson effects.

Phase-sensitive techniques help determine the symmetry of the order parameter.

Research advances understanding of pairing mechanisms in complex superconductors.

Abstract

Emerging in the 1950s, the multiband superconductivity has been considered for a long time as an approximate model in the form of a generalization of the BCS theory to the case of two bands for a more accurate quantitative description of the properties and characteristics of such superconductors as cuprates, heavy fermions compounds, metal boron carbides, fullerides, strontium ruthenate etc. due to their complex piecewise-continuous Fermi surfaces. However the discovery of the multiband structure of the superconducting state in magnesium diboride in 2001 and iron oxypnictides and chalcogenides in 2008 led to the appearance of many papers in which effects and different dependences well known for conventional single-band s-wave superconductors were reexamined. The main purpose of these studies was to reveal the symmetry type of the order parameter, which provides an important information about the mechanism of Cooper pairing in these superconductors. One of the most effective methods of obtaining information on the symmetry properties of the order parameter in the multiband superconductors is phase-sensitive techniques. This review summarizes the results of theoretical and experimental studies of the proximity and Josephson effects in systems based on multiband superconductors in contact with normal metals, insulators and other superconductors.