Conveners
Wed-Mo-Or2 - Muon Collider Magnets
- Antonio della Corte (ENEA)
- Gerard Willering (CERN)
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Bernardo Bordini (CERN)02/07/2025, 11:15Contributed Oral
The Muon Collider (MC) embodies a groundbreaking concept in circular colliders for high-energy physics, offering a unique pathway to achieve unprecedented energy and luminosity of the colliding partons while significantly reducing environmental impact compared to conventional collider technologies. A critical aspect of its feasibility lies in the development of cutting-edge superconducting...
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Samuele Mariotto02/07/2025, 11:30Contributed Oral
The Muon Collider represents an exciting proposal for a post-LHC accelerator, capable of exploring higher-energy regions with greater power consumption efficiency compared to hadronic alternatives, while avoiding synchrotron radiation limitations inherent in electron colliders.
This contribution will focus on the magnets for the Muon Collider storage ring. These magnets pose an...
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Bernardo Bordini (CERN)02/07/2025, 11:45Contributed Oral
The Muon Collider (MC) is one of the options under study as the next step for high-energy physics beyond the Large Hadron Collider. The magnets for a MC, largely based on high-temperature superconductors (HTS), bear some of the most pressing technology challenges and will require intense development and demonstration in the next years. The “target decay and capture solenoid”, a high field...
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Samuele Mariotto02/07/2025, 12:00Contributed Oral
Large particle accelerator facilities for medium-high proton and heavy ion beamlines extensively rely on normal conducting magnets which, while effective, suffer from significant energy losses due to resistive heating in their copper coils. One successful strategy for improving these facilities involves upgrading their existing infrastructure by replacing resistive magnets with magnesium...
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Mr Joe Lamont (JLab)02/07/2025, 12:15Contributed Oral
The MOLLER experiment at the Thomas Jefferson National Accelerator Facility (JLab) aims to precisely measure the weak interaction between electrons. This experiment leverages the 12 GeV electron beam and will run for three years. A crucial component of MOLLER is a system of five uniquely shaped water-cooled toroidal magnets. These magnets, possessing seven-fold symmetry, are designed to focus...
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