# SiC-YiG X band quantum sensor for sensitive surface paramagnetic   resonance applied to chemistry, biology, physics

**Authors:** J\'er\^ome Tribollet

arXiv: 1901.05073 · 2019-01-17

## TL;DR

The SiC-YiG Quantum Sensor enables highly sensitive surface EPR studies of nanometer-thick samples, offering nanoscale spatial resolution and significantly improved detection sensitivity over standard methods, with applications in chemistry, biology, and physics.

## Contribution

This work introduces a novel SiC-YiG quantum sensor combining SiC vacancies and YIG nanostripes for enhanced surface EPR detection with nanoscale precision.

## Key findings

- Sensitivity is at least five orders of magnitude higher than standard X band EPR.
- Achieves nanoscale spatial resolution of +/- 1 nm.
- Detects 2D spin concentrations down to 1/(20nm x 20nm).

## Abstract

Here I present the SiC-YiG Quantum Sensor, allowing electron paramagnetic resonance (EPR) studies of monolayer or few nanometers thick chemical, biological or physical samples located on the sensor surface. It contains two parts, a 4H-SiC substrate with many paramagnetic silicon vacancies (V2) located below its surface, and YIG ferrimagnetic nanostripes. Spins sensing properties are based on optically detected double electron-electron spin resonance under the strong magnetic field gradient of nanostripes. Here I describe fabrication, magnetic, optical and spins sensing properties of this sensor. I show that the target spins sensitivity is at least five orders of magnitude larger than the one of standard X band EPR spectrometer, for which it constitutes, combined with a fiber bundle, a powerful upgrade for sensitive surface EPR. This sensor can determine the target spins planes EPR spectrum, their positions with a nanoscale precision of +/- 1 nm, and their 2D concentration down to 1/(20nm.20nm).

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Source: https://tomesphere.com/paper/1901.05073