Complex phase-fluctuation effects correlated with granularity in superconducting NbN nanofilms

TL;DR

This study investigates complex phase fluctuations, including BKT transition and phase slips, in granular NbN nanofilms thinner than 15 nm, revealing their evolution and interplay with nanostructure properties.

Contribution

It provides experimental evidence of BKT transition and phase slips in NbN nanofilms and links these phenomena to nanostructure granularity and coherence length.

Findings

Observation of BKT transition and phase slips in NbN nanofilms

Continuous evolution from quantum to thermal phase slips

Phase phenomena linked to nanoconductive path size and coherence length

Abstract

Superconducting nanofilms are tunable systems that can host a 3D-2D dimensional crossover, leading to the Berezinskii-Kosterlitz-Thouless (BKT) superconducting transition approaching the 2D regime. Reducing further the dimensionality, from 2D to quasi-1D, superconducting nanostructures with disorder can generate quantum and thermal phase slips (PS) of the order parameter. Both BKT and PS are complex phase fluctuation phenomena of difficult experimental detection. Here, we have characterized superconducting NbN nanofilms thinner than 15 nm, on different substrates, by temperature dependent resistivity and current-voltage (I-V) characteristics. Our measurements have evidenced clear features related to the emergence of BKT transition and PS events. The contemporary observation in the same system of BKT transition and PS events and their tunable evolution in temperature and thickness, has been explained as due to the nano-conducting paths forming in a granular NbN system. In one of the investigated samples we have been able to trace and characterize the continuous evolution in temperature from quantum to thermal PS. Our analysis has established that the detected complex phase phenomena are strongly related to the interplay between the typical size of the nano-conductive paths and the superconducting coherence length.