Probing individual topological tunnelling events of a quantum field via their macroscopic consequences

TL;DR

This paper provides strong experimental evidence for individual quantum tunnelling events, known as quantum phase slips, in superconducting nanowires, revealing their macroscopic effects on switching currents at low temperatures.

Contribution

It demonstrates direct observation of quantum phase slips in homogeneous nanowires through switching current distributions, advancing understanding of quantum fluctuations in superconductors.

Findings

Quantum tunnelling events cause switching at low temperatures.

Quantum fluctuations dominate over thermal fluctuations in larger critical current wires.

Switching rate behavior supports the presence of quantum phase slips.

Abstract

Phase slips are topological fluctuation events that carry the superconducting order-parameter field between distinct current carrying states. Owing to these phase slips low-dimensional superconductors acquire electrical resistance. In quasi-one-dimensional nanowires it is well known that at higher temperatures phase slips occur via the process of thermal barrier-crossing by the order-parameter field. At low temperatures, the general expectation is that phase slips should proceed via quantum tunnelling events, which are known as quantum phase slips (QPS). Here we report strong evidence for individual quantum tunnelling events undergone by the superconducting order-parameter field in homogeneous nanowires.We accomplish this via measurements of the distribution of switching currents-the high-bias currents at which superconductivity gives way to resistive behaviour-whose width exhibits a rather counter-intuitive, monotonic increase with decreasing temperature. We outline a stochastic model of phase slip kinetics which relates the basic phase slip rates to switching rates. Comparison with this model indicates that the phase predominantly slips via thermal activation at high temperatures but at sufficiently low temperatures switching is caused by individual topological tunnelling events of the order-parameter field, i.e., QPS. Importantly, measurements on several wires show that quantum fluctuations tend to dominate over thermal fluctuations at larger temperatures in wires having larger critical currents. This fact provides strong supports the view that the anomalously high switching rates observed at low temperatures are indeed due to QPS, and not consequences of extraneous noise or hidden inhomogeneity of the wire.