Abstract
In general, the studies of finite size effects in mesoscopic superconductors have been carried out in such a way that the temperature parameter is constant in the entire system. However, we could have situations where a real sample is near a heater source, as an example. In such situations, gradients of temperature are present. On the other hand, mesoscopic superconductors are interesting systems due to the fact that they present confinement effects which influence all the vortex dynamics. Thus, in this work we studied the influence of thermal gradients on the vortex dynamics in mesoscopic superconductors. For this purposes, we used the time dependent Ginzburg-Landau equations. The thermal gradients produce an asymmetric distribution of the currents around the system which, in turn, yield interesting vortex configurations and difficult the formation of giant vortices.
Highlights
The time dependent Ginzburg-Landau (TDGL) theory has been successfully used in the last decades to describe several aspects of mesoscopic superconducting systems
We study the behavior of the vortex dynamics in mesoscopic systems in the presence of linear thermal gradients
All the dynamics were analyzed under a thermal gradient which changes the value of ψ along the x axis of the system
Summary
The time dependent Ginzburg-Landau (TDGL) theory has been successfully used in the last decades to describe several aspects of mesoscopic superconducting systems. Such systems present small size of the order of penetration depth λ(T ) and/or the coherence length ξ(T ), where T is the temperature. We study the behavior of the vortex dynamics in mesoscopic systems in the presence of linear thermal gradients.
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