Synthetic areas spread in two-dimensional Superconducting Quantum Interference Filter Arrays

TL;DR

This paper introduces a novel method to create 2D SQUID arrays with synthetic area spread using bare superconducting loops, enabling absolute magnetometry without physical area incommensurability.

Contribution

It presents a theoretical framework and experimental validation for using bare superconducting loops to simulate area spread in SQUID arrays, enhancing quantum sensor performance.

Findings

Synthetic area spread can be achieved with bare loops, matching incommensurate arrays.

Theoretical formulation links bare loop distribution to synthetic area spread.

Experimental arrays behave as predicted by the theory, confirming the approach.

Abstract

Superconducting Quantum Interference Devices (SQUIDs), formed by incorporating Josephson junctions into loops of superconducting material, are the backbone of many modern quantum sensing systems. It has been demonstrated that, by combining multiple SQUID loops into a two-dimensional (2D) array, it is possible to fabricate ultra-high-performing Radio frequency sensors. However, to function as absolute magnetometers, current-in-use arrays require the area of each SQUID loop in the array to be incommensurate. Doing so forbids the achievement of their full potential of performance, limited only by the standard quantum limit. This is because imposing incommensurability in the areas contrasts with optimised performance in each single SQUID loop. In this work, we report that by selectively inserting bare sections of a superconducting circuit with no Josephson junctions, 2D SQUID arrays can operate as an absolute magnetometer even when no physical area spread is applied. Based on a generalisation of current available theories, a complete analytical formulation for the one-to-one correspondence between the distribution of these bare loops and what we call a synthetic area spread is unveiled. This synthetic spread represents the equivalent physical spread of incommensurate SQUID loops that you would use to obtain the absolute Voltage-Magnetic Flux response if no bare loops were in use. Our work opens the way to a broader use of this technology for the fabrication of ultra-high-performance absolute quantum sensors. Our approach is also experimentally verified by fabricating several 2D Superconducting Quantum Interference Filter (SQIF) arrays incorporating bare superconducting loops and by demonstrating that they behave in alignment with what is suggested by our theory.