Coulomb-blockade and Pauli-blockade magnetometry

TL;DR

This paper explores the theoretical potential of quantum dot-based magnetometers for nanoscale magnetic field detection, demonstrating high sensitivity and in situ switching between electrical and magnetic sensing modes.

Contribution

It introduces a novel approach to magnetic field measurement using quantum dots in Coulomb and Pauli blockade regimes, highlighting their advantages for nanoscale sensing.

Findings

Sensitivity below 1 μT/√Hz with carbon nanotube quantum dots.

Potential for high spatial resolution due to small detection volume.

Hybrid sensing capability between electrical and magnetic modes.

Abstract

Scanning-probe magnetometry is a valuable experimental tool to investigate magnetic phenomena at the micro- and nanoscale. We theoretically analyze the possibility of measuring magnetic fields via the electrical current flowing through quantum dots. We characterize the shot-noise-limited magnetic-field sensitivity of two devices: a single dot in the Coulomb blockade regime, and a double dot in the Pauli blockade regime. Constructing such magnetometers using carbon nanotube quantum dots would benefit from the large, strongly anisotropic and controllable g tensors, the low abundance of nuclear spins, and the small detection volume allowing for nanoscale spatial resolution; we estimate that a sensitivity below $1 \, \mu\text{T}/\sqrt{\text{Hz}}$ can be achieved with this material. As quantum dots have already proven to be useful as scanning-probe electrometers, our proposal highlights their potential as hybrid sensors having in situ switching capability between electrical and magnetic sensing.