:''For other uses, see
Squid (disambiguation).''
'
''S''uperconducting ''Qu''antum ''I''nterference ''D''evices (SQUID)' are very sensitive
magnetometers used to measure extremely small
magnetic fields, based on superconducting loops containing
Josephson junctions.
They have noise levels as low as 3 fT·Hz
−½. For comparison, a typical refrigerator magnet produces 0.01
tesla (10
−2 T), and some processes in
animals produce very small magnetic fields between 10
−9 T to 10
−6 T.
Recently invented
SERF atomic magnetometers are more sensitive, but for decades SQUID sensors were the only way to measure very small magnetic fields.
History and design
The DC SQUID was invented in
1964 by Robert Jaklevic, John Lambe, Arnold Silver, and James Mercereau of Ford Research Labs after
B. D. Josephson postulated the
Josephson effect in
1962 and the first Josephson Junction was made by John Rowell and Philip Anderson at
Bell Labs in
1963. The RF SQUID was invented in 1965 by
James Edward Zimmerman and Arnold Silver at Ford.
There are two main types of SQUID:
DC and
RF. RF SQUIDs can work with only one
Josephson junction, which might make them cheaper to produce, but are less sensitive.
The traditional
superconducting materials for SQUIDs are pure
niobium or a
lead alloy with 10%
gold or
indium, as pure lead is unstable when its temperature is repeatedly changed. To maintain superconductivity, the entire device needs to operate within a few degrees of
absolute zero, cooled with
liquid helium.
"High temperature" SQUID sensors are more recent; they are made of
high temperature superconductors, particularly
YBCO, and are cooled by
liquid nitrogen which is cheaper and more easily handled than liquid helium. They are less sensitive than conventional "low temperature" SQUIDs but good enough for many applications.
A prototype of a Semiconductor Superconducting Quantum Interference Device (SQUID).
Uses for SQUIDs
The extreme sensitivity of SQUIDs makes them ideal for studies in biology.
Magnetoencephalography (MEG), for example, uses measurements from an array of SQUIDs to make inferences about
neural activity inside
brains. Because SQUIDs can operate at acquisition rates much higher than the highest temporal frequency of interest in the signals emitted by the brain (kHz), MEG achieves good temporal resolution. Another area where SQUIDs are used is
magnetogastrography, which is concerned with recording the weak magnetic fields of the stomach.
Probably the most common use of SQUIDs is in magnetic property measurement systems. These are turn-key systems, made by several manufacturers, that measure the magnetic properties of a material sample. This is typically done over a temperature range from that of liquid helium (~4K), to a couple of hundred degrees above room temperature.
For example,
UC Berkeley Physics Professor
John Clarke has been using SQUID's as a detector to perform
Magnetic Resonance Imaging. While high field MRI uses precession fields of one to several tesla, SQUID-detected MRI uses measurement fields that lie in the microtesla regime. Since the NMR signal drops off as the square of the magnetic field, a SQUID is used as the detector because of its extreme sensitivity. The SQUID coupled to a second-order
gradiometer and input circuit, along with the application of gradients are the fundamental entities which allows his research group to retrieve noninvasive images. SQUID-detected MRI has many advantages such as the low cost required to build such a system, its compactness, the ability to image human extremities, and its application for tumor screening.
Another application is the
scanning SQUID microscope, which uses a SQUID immersed in liquid
helium as the probe. The use of SQUIDs in
oil prospecting,
mineral exploration,
earthquake prediction and
geothermal energy surveying is becoming more widespread as superconductor technology develops; they are also used as precision movement sensors in a variety of scientific applications, such as the detection of
gravity waves. Four SQUIDs were employed on
Gravity Probe B in order to test the limits of the theory of
general relativity.
The inner workings of an early Superconducting Quantum Interference Device (SQUID).
SQUIDs in fiction
★ The
science fiction writer
William Gibson made reference to SQUIDs in his 1981 story
Johnny Mnemonic, where a genetically engineered ex-military dolphin uses a SQUID implant to read a memory device in the title character's brain.
★ In the film ''
Strange Days'', SQUIDs are used to record and play back human memories, some of which are exchanged on the
black market.
★ In
Michael Crichton's 1999 novel ''
Timeline,'' SQUIDs are mentioned as a part of the
Quantum Teleportation device developed by ITC.
★
Jon Courtenay Grimwood's novel ''
redRobe'' makes reference to SQUID probes being used to read memories and thoughts as part of a particularly invasive interrogation.
See also
★
Spallation Neutron Source Superconducting RF Cavities
★
Mineral exploration
★
Geophysics
★
Electromagnetics
External links
العربية
中国
Français
Deutsch
Ελληνική
हिन्दी
Italiano
日本語
Português
Русский
Español
