Asymmetric Stress Engineering of Dense Dislocations in Brittle Superconductors for Strong Vortex Pinning

M Han and CH Dong and C Yao and ZH Zhang and QH Zhang and Y Gong and H Huang and DL Gong and DL Wang and XP Zhang and F Liu and YP Sun and ZW Zhu and JQ Li and JY Luo and S Awaji and XL Wang and JX Xie and H Hosono and YW Ma, ADVANCED MATERIALS, 37, e13265 (2025).

DOI: 10.1002/adma.202513265

Large lossless currents in high-temperature superconductors (HTS) critically rely on dense defects with suitable size and dimensionality to pin vortices, with dislocations being particularly effective due to their 1D geometry to interact extensively with vortex lines. However, in non-metallic compounds such as HTS with rigid lattices, conventional deformation methods typically lead to catastrophic fracture rather than dislocation-mediated plasticity, making it a persistent challenge to introduce dislocations at high density. Here, an asymmetric stress field strategy is proposed using extrusion to directly nucleate a high density of dislocations in HTS by activating shear-driven lattice slip and twisting under superimposed hydrostatic compression. As demonstrated in iron-based superconductors (IBS), atomic displacements of approximate to 1 & Aring; trigger the formation of tilted dislocation lines with a density approaching that of metals. With further structural refinement, these dislocations serve as strong pinning centers that lead to a fivefold enhancement in the current-carrying capacity of IBS at 33 tesla (T), along with low anisotropy and a large irreversibility field. This work not only establishes a scalable route to engineer pinning landscapes in HTS but also offers a generalizable framework for manipulating dislocation structures in rigid crystalline systems.

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