6533b870fe1ef96bd12d05d1
RESEARCH PRODUCT
Characterization of microscopic ferromagnetic defects in thin films using magnetic microscope based on Nitrogen-Vacancy centres
Andrejs PetruhinsAndris BerzinsJanis SmitsJanis Smitssubject
Materials scienceMicroscopeFOS: Physical sciencesApplied Physics (physics.app-ph)02 engineering and technology010402 general chemistry01 natural scienceslaw.inventionMagnetic field imaginglawVacancy defectDeposition (phase transition)General Materials ScienceThin filmCondensed matter physicsPhysics - Applied Physicsequipment and supplies021001 nanoscience & nanotechnologyCondensed Matter PhysicsWide-field magnetic microscopy; Ferromagnetic thin film; Surface defect characterization; Optically detected magnetic resonance; Nitrogen-vacancy centres in diamond0104 chemical sciencesMagnetic fieldCharacterization (materials science)Ferromagnetism0210 nano-technologyDen kondenserade materiens fysikhuman activitiesdescription
In this work we present results acquired by applying magnetic field imaging technique based on Nitrogen-Vacancy centres in diamond crystal for characterization of magnetic thin films defects. We used the constructed wide-field magnetic microscope for measurements of two kinds of magnetic defects in thin films. One family of defects under study was a result of non-optimal thin film growth conditions. The magnetic field maps of several regions of the thin films created under very similar conditions to previously published research revealed microscopic impurity islands of ferromagnetic defects, that potentially could disturb the magnetic properties of the surface. The second part of the measurements was dedicated to defects created post deposition - mechanical defects introduced in ferromagnetic thin films. In both cases, the measurements identify the magnetic field amplitude and distribution of the magnetic defects. In addition, the magnetic field maps were correlated with the corresponding optical images. As this method has great potential for quality control of different stages of magnetic thin film manufacturing process and it can rival other widely used measurement techniques, we also propose solutions for the optimization of the device in the perspective of high throughput.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-10-30 | Materials Chemistry and Physics |