Superconducting magnet
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Since superconductive state can be maintained at low temperatures, the coil is typically immersed in a cryo-coolant. | Since superconductive state can be maintained at low temperatures, the coil is typically immersed in a cryo-coolant. | ||
| - | All superconducting magnets currently used for NMR spectroscopy are cooled by liquid helium. | + | All superconducting magnets currently used for NMR spectroscopy are cooled by liquid helium at normal atmospheric pressure or at decreased pressure. |
Strength of the magnetic field is determined by the current density contained in the superconducting coil. | Strength of the magnetic field is determined by the current density contained in the superconducting coil. | ||
| - | The higher is current density the higher is the magnetic field and the corresponding Larmor frequency. | + | The higher is current density the higher is the magnetic field and the corresponding Larmor frequency. |
| + | Most of produced SC (superconducting) magnets have/had 1H frequency 100, 180, 200, 220, 250, 270, 300, 360, 400, 500, 600, 700, 750, 800, 850, 900, 920, 950 and 1000 MHz | ||
Current density capacity can be increased in a given coil by improving joint and wire technology. | Current density capacity can be increased in a given coil by improving joint and wire technology. | ||
Revision as of 14:51, 17 October 2009
Solenoid wound with superconducting wire provides the basis of every high-frequency NMR magnet.
Since superconductive state can be maintained at low temperatures, the coil is typically immersed in a cryo-coolant. All superconducting magnets currently used for NMR spectroscopy are cooled by liquid helium at normal atmospheric pressure or at decreased pressure.
Strength of the magnetic field is determined by the current density contained in the superconducting coil. The higher is current density the higher is the magnetic field and the corresponding Larmor frequency. Most of produced SC (superconducting) magnets have/had 1H frequency 100, 180, 200, 220, 250, 270, 300, 360, 400, 500, 600, 700, 750, 800, 850, 900, 920, 950 and 1000 MHz
Current density capacity can be increased in a given coil by improving joint and wire technology. When improving those technologies is impractical some increase in current capacity can be achieved by cooling the coil even further. The latter is the principle of operation of the "pumped" magnet systems (where temperature of liquid He is decreased by actively pumping evaporating He gas)
