Dr Michael Cuthbert, Commercial Director of Oxford Instruments NanoScience said, «The completion of this magnet is confirmation of Oxford Instruments» world - class capability to develop state - of - the - art, high field
superconducting magnet systems.
Not exact matches
«For MRI
systems, we're applying
superconducting magnets to make lower - cost
systems with higher image quality,» Longtin said.
Even if a device with
superconducting wires were shielded from
magnets, any electricity flowing through the
system would generate an unwanted magnetic field.
Commonwealth Fusion
Systems has pledged to build a commercial fusion reactor based on new
superconducting magnets.
Researchers will position the tritium - loaded graphene inside the first
superconducting magnet, whose field strength is similar to the MRI
systems that hospitals and clinics use.
Since a synchrotron requires very powerful magnetic fields, they would need a
superconducting magnet, and a cryogen
system to keep the
magnets cold, which requires a source of helium.
The 32 T
superconducting system is made from two primary sections, an outsert section delivering 15 Tesla in a 250 mm wide bore
magnet developed by Oxford Instruments Nanoscience (OINS) using advanced Low Temperature Superconductor (LTS) materials operating at 4.2 Kelvin and an insert section delivering 17 Tesla in 34 mm cold bore developed by our colleagues at NHMFL using advanced High Temperature Superconductor (HTS) materials manufactured by Superpower Inc..