Design for a Muon Front End with Magnetically Shielded RF Cavities

“…In the shielded lattice, the magnetic field on the RF cavities is reduced by stretching the lattice and adding shielding around the coils. This reduces the acceptance and performance of the system but much of the performance can be recovered by reducing the geometric emittance of the beam by means of an initial acceleration after the phase rotation system [225]. …”

“…Indications that the maximum cavity-gradient may be reduced in magnetic fields have led to the consideration of frontend lattices that give adequate performance should the RF cavities not reach the gradients specified for the magnetic field configuration of the baseline lattice for the IDS-NF muon front end. The performance of the baseline lattices, along with that of the modified lattices, has been computed [220,[223][224][225][226][227]. Particle losses and energy deposition in the front end have been computed, and methods to reduce their impact are beginning to be studied.…”

Interim Design Report

“…In the shielded lattice, the magnetic field on the RF cavities is reduced by stretching the lattice and adding shielding around the coils. This reduces the acceptance and performance of the system but much of the performance can be recovered by reducing the geometric emittance of the beam by means of an initial acceleration after the phase rotation system [225]. …”

“…Indications that the maximum cavity-gradient may be reduced in magnetic fields have led to the consideration of frontend lattices that give adequate performance should the RF cavities not reach the gradients specified for the magnetic field configuration of the baseline lattice for the IDS-NF muon front end. The performance of the baseline lattices, along with that of the modified lattices, has been computed [220,[223][224][225][226][227]. Particle losses and energy deposition in the front end have been computed, and methods to reduce their impact are beginning to be studied.…”

Interim Design Report