Commensurability, Jamming, and Dynamics for Vortices in Funnel Geometries

TL;DR

This study uses simulations to explore vortex behavior in funnel-shaped superconductors, revealing commensurability effects, jamming phenomena, and unique flow dynamics that resemble hourglass sand behavior.

Contribution

It demonstrates how vortex configurations and flow phases in funnel geometries differ from isolated samples, highlighting the effects of vortex-vortex interactions and geometry on depinning and flow.

Findings

Vortex configurations vary with matching fields and differ from isolated samples.

Depinning force increases with vortex density due to crowding effects.

Vortex flow exhibits elastic and plastic phases with characteristic transport features.

Abstract

We use numerical simulations to examine vortex states and dynamics in periodic funnel geometries where a drive is applied in the easy flow direction. We show that this system exhibits a number of different commensurability effects when the vortex configurations match to both the periodicity of the array and the geometry of the funnels. The vortex configurations in this system are generally different from those observed for single isolated triangular superconducting samples due to the coupling of vortices in adjacent funnels. At certain matching fields, peaks in the critical current are absent due to the particular vortex configurations that occur at these fields. We find that the overall depinning force increases with increasing vortex density as a result of the enhanced vortex-vortex interactions caused by a crowding effect at the funnel tips. When a system becomes less mobile as a result of increased particle interactions, it is said to exhibit a jamming behavior. Under an applied drive we observe a series of elastic and plastic vortex flow phases which produce pronounced features such as jumps or dips in the transport curves. In all of the flow phases, only one vortex can pass through the funnel tip at a time due to the vortex-vortex repulsion forces. As a consequence of this constraint, we observe the remarkable result that the sum of the vortex velocities at a fixed drive remains nearly constant with increasing magnetic field B rather than increasing linearly. This result is similar to the behavior of sand in an hourglass. We also show how noise fluctuations can be used to distinguish the different flow phases. Our results should be readily generalizable to other systems of particles flowing in periodic funnel geometries, such as colloids or Wigner crystals.