Homogeneous magnets make data clearer for scientists. The MagLab has some of the most homogeneous magnets in the world.
The Series Connected Hybrid magnet that is under fabrication at the NHMFL will utilize current leads containing high temperature superconductor to deliver 20 kA with low heat loads to the helium circuit. The leads have been successfully tested and are ready for installation into the magnet system.
To get millions of watts of electricity into our magnets, we need a couple of these.
In 2014, MagLab completed the world's strongest magnet for neutron scattering for the Helmholtz Centre Berlin (HZB).
The MagLab has delivered the resistive insert coils for the 25-Tesla Series Connected Hybrid Magnet for the Helmholtz-Zentrum Berlin. This magnet system includes a unique conical warm bore with 30 degree opening angle and will be used for neutron-scattering experiments and an unprecedented 25T central field. This constitutes a 47% increase in magnetic field available for these experiments while also providing an increase in solid-angle.
The MagLab has successfully completed construction of the cold-mass of a series-connected hybrid magnet for the Helmholtz-Zentrum Berlin.
TALLAHASSEE, Fla. — MagLab engineers and visiting Berlin scientists are celebrating a major accomplishment as they prepare to ship a critical section of a new record-breaking magnet to Germany.
This magnet can be used for both condensed matter science physics and NMR spectroscopy. It is the strongest magnet in the world for NMR.
MagLab engineers are building two cable-in-conduit superconducting coils for hybrid magnets, each with a resistive inner coil and a superconducting outer coil.
Contact: KATHLEEN LAUFENBERG
Scientists at the National High Magnetic Field Laboratory at The Florida State University are working to open a new frontier in chemistry, biology and materials studies, thanks to a recent $1.3 million grant from the National Science Foundation (NSF).