Multistability and Self-Organization in Disordered SQUID Metamaterials

TL;DR

This paper explores how disorder in SQUID metamaterials can enhance bistability and self-organization, leading to tunable magnetic responses including negative permeability, with potential applications in superconducting metamaterials.

Contribution

It demonstrates that weak disorder promotes self-organization and broadens bistability regions in SQUID metamaterials, revealing new magnetic properties.

Findings

Disorder enhances synchronization and bistability.

Nearly homogeneous states emerge with weak disorder.

Negative magnetic permeability occurs at low power and specific frequencies.

Abstract

Planar arrays of magnetoinductively coupled rf SQUIDs belong to the emergent class of superconducting metamaterials that encompass the Josephson effect. SQUID metamaterials acquire their electromagnetic properties from the resonant characteristics of their constitutive elements, i.e., the individual rf SQUIDs, which consist of a superconducting ring interrupted by a Josephson junction. We investigate the response of a two-dimensional SQUID metamaterial to frequency variation of an applied alternating magnetic field in the presence of disorder, arising from critical current fluctuations of the Josephson elements; in effect, the resonance frequencies of individual SQUIDs are distributed randomly around a mean value. Bistability is observed in the total current-frequency curves both in ordered and disordered SQUID metamaterials; moreover, bistability is favoured by disorder through the improvement of synchronization between SQUID oscillators. Relatively weak disorder widens significantly the bistability region by helping the system to self-organize itself and leads to nearly homogeneous states that change smoothly with varying frequency. Moreover, the total current of the metamaterial is enhanced compared with that of uncoupled SQUIDs, through the synergetic action of coupling and synchronization. Multistability of nearly homogeneous states allows the metamaterial to exhibit different magnetic responses corresponding to different values of the magnetic permeability. At low power of the incident field, high-current states exhibit extreme diamagnetic properties corresponding to negative magnetic permeability in a narrow frequency region.