Intertwined effects of elastic deformation and damage on vortex pinning and Jc degradation in polycrystalline superconductors

TL;DR

This paper develops a multi-scale theoretical framework to understand how elastic deformation and damage affect vortex pinning and critical current density (Jc) degradation in polycrystalline superconductors, validated by experiments.

Contribution

It introduces a novel multi-scale model to analyze reversible and irreversible Jc degradation due to strain, linking microscopic damage to electromagnetic measurements.

Findings

Damage evolution can be estimated via Jc measurements.

Strain influences vortex pinning and Jc degradation.

Model applies to biaxial mechanical loads.

Abstract

The damage and the critical current density (Jc) degradation of polycrystalline superconductors induced by strain dramatically influence their performance in applications. Unfortunately, the state-of-the-art experimental techniques are unable to detect the damage of internal polycrystalline structures and the microscopic superconductivity in the presence of strain. We propose a groundbreaking multi-scale theoretical framework aimed at revealing the underlying physical mechanisms of the reversible and irreversible Jc degradation induced by the strain through tackling the complex intertwined effects of elastic deformation and damage on the superconductivity of grain boundaries and the associated vortex pinning. The results are well validated by experimental measurements. Utilizing the benchmarked physical model, we demonstrate that the damage evolutions of polycrystalline superconductors in the presence of strain can be approximately estimated by means of the electromagnetic experiments on Jc. Furthermore, we also discuss the characteristics of damage and Jc degradation of polycrystalline superconductors subjected to biaxial mechanical loads. The findings will pave the way to investigate the tunable vortex pinning and Jc of superconductors by strain, and to develop a brand new electromagnetic method to manifest the damage of polycrystalline superconductors.