Title :
Spatial Resolution Assessment of Nano-SQUIDs Made by Focused Ion Beam
Author :
Hao, L. ; Macfarlane, J.C. ; Gallop, J.C. ; Romans, E. ; Cox, D. ; Hutson, D. ; Chen, J.
Author_Institution :
Nat. Phys. Lab., Teddington
fDate :
6/1/2007 12:00:00 AM
Abstract :
The ability to reduce SQUID dimensions into the sub-micrometer or nanometer regime points the way towards novel applications, particularly in emerging fields such as quantum information processing, single-photon/particle detection, and experimental studies of nano-scale entities such as Bose-Einstein condensates. We report here on our ongoing work combining traditional thin-film and photolithographic fabrication processes with computer-aided-design software and focused ion beam milling to realize sub-micrometer superconducting structures. Their magnetic field sensitivity, noise behavior, spatial resolution, and prospects for magnetic spin detection are discussed.
Keywords :
Bose-Einstein condensation; SQUIDs; focused ion beam technology; ion beam lithography; nanolithography; particle detectors; photolithography; quantum computing; Bose-Einstein condensates; computer-aided-design software; focused ion beam milling; magnetic field sensitivity; magnetic spin detection; nanoSQUID; noise behavior; particle detection; photolithography; quantum information processing; single-photon detection; spatial resolution; sub-micrometer superconducting structure; thin film fabrication; Application software; Fabrication; Information processing; Ion beams; Magnetic fields; Milling; SQUIDs; Spatial resolution; Superconducting device noise; Superconducting thin films; Magnetic field sensitivity; nanoscale SQUID; spatial resolution; superconductor;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2007.898068
