Denys Makarov's team at HZDR, together with the Qnami Application lab, demonstrated a method for creating binary states in antiferromagnetic materials.
Sergei Trofimov and Boris Naydenov from the Helmholtz Center in Berlin used Qnami Quantum Foundry diamond plates to achieve nanoscale quantum sensing with 13 nm resolution by combining confocal and atomic-force microscopy techniques.
Paul Stevenson’s research at Northeastern University utilized the Qnami ProteusQ microscope to enhance vector magnetometry, allowing precise measurement of both parallel and perpendicular stray fields in complex materials like bismuth ferrite.
Researchers developed diamond probes that enhanced nitrogen-vacancy center signal detection, enabling improved quantum sensing for Qnami Quantilever MX+ probes
Scanning NV Magnetometry proves how a novel combination of van der Waals materials is the easy and effective chiral quantum light source of the future.
Applying inhomogeneous strain to chromium oxide thin films induces a strong vertical gradient of the Neel temperature inferred through scanning NV magnetometry measurements.
Scanning NV Magnetometry unveiled for the first time the nanoscale mechanics of antiferromagnetic domain walls opening new avenues for antiferromagnetic spintronics.
Scanning NV Magnetometry unlocks the characterization of the effects of strain and electrical fields on exotic antiferromagnetic spin textures in multiferroics.