Find out more about Scanning NV Magnetometry in this curated collection of relevant literature. Explore how this powerful technique is advancing research across various fields by providing precise insights into magnetic phenomena at the nanoscale.
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.
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.
Researchers developed diamond probes that enhanced nitrogen-vacancy center signal detection, enabling improved quantum sensing for Qnami Quantilever MX+ probes
This work demonstrates how vector measurements improve the accuracy of reconstructing current density and magnetization in 2D materials using stray magnetic field data.
Patrick Maletinsky’s group pioneered the use of scanning nitrogen-vacancy magnetometry to achieve the first nanoscale imaging of magnetism in 2D materials.
This groundbreaking work revolutionized quantum nanoscale sensing by using nitrogen-vacancy (NV) centers in diamonds. The innovative approach enabled highly sensitive magnetic imaging at the nanoscale.
This technical note explains how spatial resolution is defined in Scanning NV Magnetometry. For a given distance d between the NV center and the scanned surface, the best achievable lateral spatial resolution is 0.86 d.
