Vortex Dynamics in Amorphous MoSi Superconducting Thin Films

TL;DR

This study investigates how photon irradiation influences vortex dynamics in amorphous MoSi superconducting thin films, revealing enhanced vortex depinning and implications for device optimization.

Contribution

It provides new insights into the effect of irradiation on vortex depinning and potential barriers in amorphous MoSi superconductors, aiding future device development.

Findings

Photon irradiation enhances vortex depinning in a MoSi films.

Critical vortex velocity remains unaffected by irradiation.

Irradiation reduces potential barriers, mitigating inhomogeneity effects.

Abstract

Vortex dynamics in superconductors have received a great deal of attention from both fundamental and applied researchers over the past few decades. Because of its critical role in the energy relaxation process of type II superconductors, vortex dynamics have been deemed a key factor for the emerging superconducting devices, but the effect of irradiation on vortex dynamics remains unclear. With the support of electrical transport measurements under external magnetic fields and irradiation, photon effect on vortex dynamics in amorphous MoSi (a MoSi) superconducting thin films are investigated in this work. The magnetic field dependent critical vortex velocity v* derived from the Larkin Ovchinnikov model is not significantly affected by irradiation. However, vortex depinning is found to be enhanced by photon-induced reduction in potential barrier, which mitigates the adverse effect of film inhomogeneity on superconductivity in the a MoSi thin films. The thorough understanding of the vortex dynamics in a MoSi thin films under the effect of external stimuli is of paramount importance for both further fundamental research in this area and optimization of future superconducting devices.