Blockade of vortex flow by thermal fluctuations in atomically thin clean-limit superconductors

TL;DR

This paper demonstrates that in atomically thin superconductors, thermal fluctuations can cause non-monotonic resistance behavior below the transition temperature, challenging traditional expectations of vortex motion suppression at lower temperatures.

Contribution

It provides the first experimental evidence of non-monotonic resistance due to thermal vortex fluctuations in clean-limit, atomically thin superconductors, supported by analytical and numerical models.

Findings

Resistance shows a minimum and then increases as temperature decreases.

Thermal fluctuations influence vortex mobility and dissipation.

The two-fluid vortex model explains the experimental observations.

Abstract

Resistance in superconductors arises from the motion of vortices driven by flowing supercurrents or external electromagnetic fields and may be strongly affected by thermal or quantum fluctuations. The common expectation borne out in previous experiments is that as the temperature is lowered, vortex motion is suppressed, leading to a decreased resistance. A new generation of materials provides access to the previously inaccessible regime of clean-limit superconductivity in atomically thin superconducting layers. We show experimentally that for few-layer 2H-NbSe$_2$ the resistance below the superconducting transition temperature may be non-monotonic, passing through a minimum and then increasing again as temperature is decreased further. The effects exists over a wide range of current and magnetic fields, but is most pronounced in monolayer devices at intermediate currents. Analytical and numerical calculations confirm that the findings can be understood in a two-fluid vortex model, in which a fraction of vortices flow in channels while the rest are pinned but thermally fluctuating in position. We show theoretically that the pinned, fluctuating vortices effectively control the mobility of the free vortices. The findings provide a new perspective on fundamental questions of vortex mobility and dissipation in superconductors.