Magneto-optical imaging of thin magnetic films using spins in diamond

TL;DR

This paper introduces a diamond-based wide-field magnetic imaging technique using nitrogen-vacancy spins, enabling real-time, high-resolution, ambient-condition imaging of magnetic fields from thin ferromagnetic films.

Contribution

It demonstrates a novel all-optical magnetic imaging method with sub-micron resolution and high sensitivity, surpassing limitations of existing techniques.

Findings

Achieved 440 nm spatial resolution at video frame rates

Demonstrated imaging without microwave excitation

Potential for sub-μT sensitivity and millisecond temporal resolution

Abstract

Imaging the fields of magnetic materials provides crucial insight into the physical and chemical processes surrounding magnetism, and has been a key ingredient in the spectacular development of magnetic data storage. Existing approaches using the magneto-optic Kerr effect (MOKE), x-ray and electron microscopy have limitations that constrain further development, and there is increasing demand for imaging and characterisation of magnetic phenomena in real time with high spatial resolution. In this work, we show how the magneto-optical response of an array of negatively-charged nitrogen-vacancy spins in diamond can be used to image and map the sub-micron stray magnetic field patterns from thin ferromagnetic films. Using optically detected magnetic resonance, we demonstrate wide-field magnetic imaging over 100x100 {\mu}m^2 with a diffraction-limited spatial resolution of 440 nm at video frame rates, under ambient conditions. We demonstrate a novel all-optical spin relaxation contrast imaging approach which can image magnetic structures in the absence of an applied microwave field. Straightforward extensions promise imaging with sub-{\mu}T sensitivity and sub-optical spatial and millisecond temporal resolution. This work establishes practical diamond-based wide-field microscopy for rapid high-sensitivity characterisation and imaging of magnetic samples, with the capability for investigating magnetic phenomena such as domain wall and skyrmion dynamics and the spin Hall effect in metals.