Bowstring effect as a trigger for flux instabilities in thin superconductors

Abstract

Magnetic vortices resemble bowstrings stretched across a corner at the initial stage of their penetration into a flat superconducting sample of a rectangular cross-section. As the external magnetic field He reaches the threshold level Hth, a bowstring is "released" and instantaneously contracted in length with a substantial heat generation. This heat can serve as a trigger for nucleation of a flux instability (avalanche). At He ≈ 2Hth a usual vortex penetration starts at flat edges, and the bowstring mechanism is no longer effective. We describe the geometry of bowstring-like vortices, find Hth for disk and strip shaped superconductors as a function of their thickness to width ratio, and determine the heat effect related to a bowstring release. Our results enable a novel treatment of numerous experimental data on flux instabilities and avalanche type penetration in flat superconducting samples. A moderate anisotropy of a superconducting penetration depth (λc > λab) diminishes or even completely removes the bowstring effect. This explains the absence of spontaneous instabilities in epitaxial YBa2Cu3O7-δ films at all temperatures and in MgB2 above 10 K.