Explore key research made possible with ProteusQ. Discover how it’s advancing studies in magnetic textures, spin dynamics, and nanoscale current flows, driving innovation in materials science and spintronics. Dive into the literature shaping the future of quantum sensing.
Swastik Kar’s group at Northeastern University used AC magnetometry on the Qnami ProteusQ to show that a permalloy nanowire can be used to concentrate RF fields into sub 300nm regions.
In a recent study on conducting ferroelectric domain walls, researchers used scanning NV magnetometry to directly visualize current flow at the nanoscale. These measurements were performed using the Qnami ProteusQ. The results challenge previous assumptions about current distribution […]
Researchers led by Ramamoorthy Ramesh used the Qnami ProteusQ™ quantum microscope to uncover how complex labyrinthine spin cycloids and their topological defects emerge in noncollinear antiferromagnets.
Denys Makarov's team at HZDR, together with the Qnami Application lab, demonstrated a method for creating binary states in antiferromagnetic materials.
Researchers led by Benjamin Lawrie used NV relaxometry on the Qnami ProteusQ system to reveal critical behavior in a high-Tc ferromagnetic oxide, providing new insights into phase transitions at the nanoscale.
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 led by Jacopo Forneris have demonstrated the fabrication of germanium-vacancy (GeV) color center arrays in diamond nanopillars, showcasing the Quantum Foundry’s expertise in nanopatterning for quantum photonics.
Vincent Garcia’s team, using ProteusQ, demonstrated electrically controlled topological states in BiFeO₃, advancing reconfigurable antiferromagnetic spintronics.
Ramamoorthy Ramesh’s team, using Scanning NV data from Proteus Q, demonstrated ferroelectric control of magnons in BiFeO₃, enabling energy-efficient spin transport for low-dissipation nanoelectronics.
Felix Casanova's team used Qnami products to demonstrate voltage-controlled magnetization switching and reading in nanodevices, paving the way for low-power magnetoelectric spin-orbit logic.
Scanning NV Magnetometry unlocks the characterization of the effects of strain and electrical fields on exotic antiferromagnetic spin textures in multiferroics.
Scanning NV Magnetometry (SNVM) is a versatile, high-resolution technique for electronic device failure analysis, enabling precise sensing of currents, temperature, magnetic fields, and AC fields.
