Superconducting quantum interference devices: State of the art and applications
Kleiner, R.
Koelle, D.
Ludwig, F.
Clarke, J.
Phys. Inst.-Exp.phys., Univ. Tubingen, Germany;
This paper appears in: Proceedings of the IEEE
Publication Date: Oct. 2004
Volume: 92,
Issue: 10
On page(s): 1534- 1548
ISSN: 0018-9219
INSPEC Accession Number: 8124789
Digital Object Identifier: 10.1109/JPROC.2004.833655
Current Version Published: 2004-09-20
Abstract
Superconducting quantum interference devices (SQUIDs) are sensitive detectors of magnetic flux. A SQUID consists of a superconducting loop interrupted by either one or two Josephson junctions for the RF or dc SQUID, respectively. Low transition temperature (Tc) SQUIDs are fabricated from thin films of niobium. Immersed in liquid helium at 4.2 K, their flux noise is typically 10-6Φ0 Hz-12/, where Φ0≡h/2e is the flux quantum. High-Tc SQUIDs are fabricated from thin films of YBa2Cu3O7-x, and are generally operated in liquid nitrogen at 77 K. Inductively coupled to an appropriate input circuit, SQUIDs measure a variety of physical quantities, including magnetic field, magnetic field gradient, voltage, and magnetic susceptibility. Systems are available for detecting magnetic signals from the brain, measuring the magnetic susceptibility of materials and geophysical core samples, magnetocardiography and nondestructive evaluation. SQUID "microscopes" detect magnetic nanoparticles attached to pathogens in an immunoassay technique and locate faults in semiconductor packages. A SQUID amplifier with an integrated resonant microstrip is within a factor of two of the quantum limit at 0.5 GHz and will be used in a search for axions. High-resolution magnetic resonance images are obtained at frequencies of a few kilohertz with a SQUID-based detector.
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