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Tesla Magnet Bodes Well for NMR, MRI Science

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TALLAHASSEE, Fla., August 11 -- The National High Magnetic Field Laboratory (NHMFL), funded by the National Science Foundation and the State of Florida, said it has achieved a world record in magnet development with the successful testing of its 21.1 Tesla superconducting ultrawide-bore nuclear magnetic resonance (NMR) magnet. The magnet reached full field on July 21 and will remain at field for years, perhaps decades, to come.

A team of engineers headed by Denis Markiewicz, Tom Painter, Iain Dixon and Jim Ferner at the NHMFL developed, designed, manufactured and tested the magnet system. The product of this 13-year effort stands 16 feet tall, weighs more than 30,000 pounds and has a stored energy of 40 megajoules. No other magnet in the world can produce 21.1 Tesla for NMR and magnetic resonance imaging (MRI) science in a 105-mm warm bore.

NHMFL Director Greg Boebinger said, "This very powerful and ultrawide bore magnet was an extremely challenging system to build, and it represents a significant engineering accomplishment. It is the crown jewel of the laboratory’s NMR spectroscopy and imaging program -- a joint effort between the National High Magnetic Field Laboratory in Tallahassee and in Gainesville."

The magnet is a concentric assembly of ten superconducting coils connected in series and operated at 1.7 K (-456.6 Fahrenheit). Each coil is wound with a monolithic superconductor, composed of either niobium-tin (Nb3Sn) or niobium-titanium (NbTi) filaments in a copper matrix. To support the magnetic loading, the coils are configured with stainless steel overbanding and are vacuum impregnated with cryogenically tough epoxy for structural support. The high current density coils produce a uniform field of 21.1 Tesla to one part in one billion in a volume 64 times larger than that of typical NMR systems. Small adjustments to field homogeneity are achieved with a set of superconducting shim coils that fine-tune the magnetic field. Fabrication of the NbTi and shim coils occurred in cooperation with an industrial partner, Intermagnetics General Corp.

"We are extremely excited about the prospects of exploring new avenues in chemical and biomedical science with this one-of-a-kind magnet system that will have an operating frequency of 900 MHz for NMR spectroscopy and MRI," said NMR Director Tim Cross.

The ultrawide bore (105 mm) is the unique aspect of this magnet that will permit a much greater range of scientific experiments than would be possible in standard 52-mm bore magnets. The NHMFL said science performed on this unique national resource will range from materials research to macromolecular biological structure determination and noninvasive magnetic resonance imaging of laboratory animals.

"With this instrument, scientists from around the world as well as those at the NHMFL will be able to expand the horizons of scientific investigation with NMR and MRI technologies," the NHMFL said in a statement.


For more information, visit: www.magnet.fsu.edu


Published: August 2004
Glossary
nuclear magnetic resonance
A phenomenon, exploited for medical imaging, in which the nuclei of material placed in a strong magnetic field will absorb radio waves supplied by a transmitter at particular frequencies. The energy of the radio-frequency photons is used to promote the nucleus from a low-energy state, in which the nuclear spin is aligned parallel to the strong magnetic field, to a higher-energy state in which the spin is opposed to the field. When the source of the radio waves is turned off, many nuclei will...
tesla
The magnetic flux density given by a magnetic flux of one weber per square meter. (T).
industrialmagnetMRINational High Magnetic Field LaboratoryNews & FeaturesNHMFLNMRnuclear magnetic resonanceTeslaTesla Magnet

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