A high performance Nb nano-SQUID with a three-dimensional structure

TL;DR

This paper presents a novel three-dimensional niobium nano-SQUID with enhanced flux modulation, low noise, and high magnetic field range, advancing the potential for single electron spin detection.

Contribution

The authors developed a fabrication process for 3-D Nb nano-SQUIDs with independently tunable nano-bridge junctions, improving flux modulation and device performance.

Findings

Achieved up to 45.9% flux modulation depth.

Measured flux noise as low as 0.34 μΦ₀/Hz^{1/2}.

Operates in magnetic fields greater than 0.5 T.

Abstract

A superconducting quantum interference device (SQUID) miniaturized into nanoscale is promising in the inductive detection of a single electron spin. A nano-SQUID with a strong spin coupling coefficient, a low flux noise, and a wide working magnetic field range is highly desired in a single spin resonance measurement. Nano-SQUIDs with Dayem-bridge junctions excel in a high working field range and in the direct coupling from spins to the bridge. However, the common planar structure of nano-SQUIDs is known for problems such as a shallow flux modulation depth and a troublesome hysteresis in current-voltage curves. Here, we developed a fabrication process for creating three-dimensional (3-D) niobium (Nb) nano-SQUIDs with nano-bridge junctions that can be tuned independently. Characterization of the device shows up to 45.9 % modulation depth with a reversible current-voltage curve. Owning to the large modulation depth, the measured flux noise is as low as 0.34 \mu\Phi$_0$/Hz$^{1/2}$. The working field range of the SQUID is greater than 0.5 T parallel to the SQUID plane. We believe that 3-D Nb nano-SQUIDs provide a promising step toward effective single-spin inductive detection.