Add to ORKGA multilayer high field dipole magnet has been designed for future particle accelerators. The magnet has eight layers of a Nb3Sn outsert coil and four layers of a Bi-2212 insert coil (see Figs. 1 and 2). The layers are graded, delivering a short-sample field of 17.7 T in a 40-mm bore. The coil layers are of a canted cosine-theta design - with ribs and spars that guide and support the coil windings, shape the field, intercept Lorentz forces, and minimize conductor prestress. We present a general overview of the concept and report on the magnetic and mechanical design including an initial cost estimate and construction plan
After LHC is turned off, a new accelerator machine will be needed in order to explore unknown region...
The high magnetic fields required for future accelerator magnets can only be achieved with Nb3Sn, ot...
It can be shown that, by superposing two solenoid-like thin windings that are oppositely skewed (til...
A four-layer canted-cosine-theta 16-T dipole has been designed as a possible candidate for future ha...
A four-layer canted-cosine-theta 16-T dipole has been designed as a possible candidate for future ha...
Advances in superconducting magnet technology have historically enabled the construction of new, hig...
International audienceHybrid magnets are currently under consideration as an economically viable opt...
The critical current density of Bi-2212 round wires has seen significant improvement over the past t...
The Superconducting Magnet Group, at Lawrence Berkeley National Laboratory (LBNL), has been developi...
The U.S. Magnet Development Program (MDP) is exploring the possibility of combining low-and higherat...
Canted-Cosine-Theta (CCT) magnet is an accelerator magnet that superposes fields of nested and tilte...
A two-layer Canted-Cosine-Theta (CCT) superconducting dipole magnet was built and tested. The magnet...
With the Large Hadron Collider (LHC) up and running, studies have started for its successor. Under s...
The next generation particle accelerators will need to increase by an order of magnitude the center-...
Next generation of dipole magnets with field higher than 16 T are considered for future particle col...
After LHC is turned off, a new accelerator machine will be needed in order to explore unknown region...
The high magnetic fields required for future accelerator magnets can only be achieved with Nb3Sn, ot...
It can be shown that, by superposing two solenoid-like thin windings that are oppositely skewed (til...
A four-layer canted-cosine-theta 16-T dipole has been designed as a possible candidate for future ha...
A four-layer canted-cosine-theta 16-T dipole has been designed as a possible candidate for future ha...
Advances in superconducting magnet technology have historically enabled the construction of new, hig...
International audienceHybrid magnets are currently under consideration as an economically viable opt...
The critical current density of Bi-2212 round wires has seen significant improvement over the past t...
The Superconducting Magnet Group, at Lawrence Berkeley National Laboratory (LBNL), has been developi...
The U.S. Magnet Development Program (MDP) is exploring the possibility of combining low-and higherat...
Canted-Cosine-Theta (CCT) magnet is an accelerator magnet that superposes fields of nested and tilte...
A two-layer Canted-Cosine-Theta (CCT) superconducting dipole magnet was built and tested. The magnet...
With the Large Hadron Collider (LHC) up and running, studies have started for its successor. Under s...
The next generation particle accelerators will need to increase by an order of magnitude the center-...
Next generation of dipole magnets with field higher than 16 T are considered for future particle col...
After LHC is turned off, a new accelerator machine will be needed in order to explore unknown region...
The high magnetic fields required for future accelerator magnets can only be achieved with Nb3Sn, ot...
It can be shown that, by superposing two solenoid-like thin windings that are oppositely skewed (til...