Evidence for temperature dependent spin-diffusion as a mechanism of intrinsic flux noise in SQUIDs

TL;DR

This paper investigates the temperature-dependent flux noise in SQUIDs, proposing a spin-diffusion model that explains experimental observations and suggests proximity to a spin-glass phase transition.

Contribution

It introduces a spin-diffusion model for flux noise in SQUIDs and demonstrates its consistency with experimental data across multiple devices and temperatures.

Findings

Flux noise increases with temperature and fits a spin-diffusion model.

The spin-diffusion constant shows temperature dependence, indicating proximity to a spin-glass transition.

Experimental data supports the spin-diffusion mechanism as a key factor in flux noise.

Abstract

The intrinsic flux noise observed in superconducting quantum interference devices (SQUIDs) is thought to be due to the fluctuation of electron spin impurities, but the frequency and temperature dependence observed in experiments do not agree with the usual 1/f models. We present theoretical calculations and experimental measurements of flux noise in rf-SQUID flux qubits that show how these observations, and previous reported measurements, can be interpreted in terms of a spin-diffusion constant that increases with temperature. We fit measurements of flux noise in sixteen devices, taken in the 20-80 mK temperature range, to the spin-diffusion model. This allowed us to extract the spin-diffusion constant and its temperature dependence, suggesting that the spin system is close to a spin-glass phase transition.