A   B   C   D   E   F   G   H   I   J   K   L   M   N   O   P   Q   R   S   T   U   V   W   X   Y   Z  

Rogers, C.T.

Paper Title Page
WEPE050 Alternative Muon Front-end for the International Design Study (IDS) 3455
 
  • C.T. Rogers
    STFC/RAL/ASTeC, Chilton, Didcot, Oxon
  • A. Alekou
    Imperial College of Science and Technology, Department of Physics, London
  • M. Martini, G. Prior
    CERN, Geneva
  • D.V. Neuffer
    Fermilab, Batavia
  • D. Stratakis
    BNL, Upton, Long Island, New York
  • C. Y. Yoshikawa
    Muons, Inc, Batavia
  • M.S. Zisman
    LBNL, Berkeley, California
 
 

We discuss alternative designs of the muon capture front end of the Neutrino Factory International Design Study (IDS). In the front end, a proton bunch on a target creates secondary pions that drift into a capture channel, decaying into muons. A sequence of RF cavities forms the resulting muon beams into strings of bunches of differing energies, aligns the bunches to (nearly) equal central energies, and initiates ionization cooling. This design is affected by limitations on accelerating gradients within magnetic fields. The effects of gradient limitations are explored, and mitigation strategies are presented.

 
WEPE051 Muon Cooling Performance in Various Neutrino Factory Cooling Cell Configurations using G4MICE 3458
 
  • A. Alekou, J. Pasternak
    Imperial College of Science and Technology, Department of Physics, London
  • C.T. Rogers
    STFC/RAL/ASTeC, Chilton, Didcot, Oxon
 
 

The Neutrino Factory is a planned particle accelerator complex that will produce an intense, focused neutrino beam, using neutrinos from muon decay. Such high neutrino intensities can only be achieved by reducing the muon beam emittance using an ionization cooling system. The G4MICE software is used to study the performance of various cooling cell configurations. A comparison is drawn between the cooling in the FS2 cells, the baseline Neutrino Factory and doublet cells. The beam dynamics in each of cooling channels are presented. The lattices are compared with respect to the equilibrium emittance, muon transmission, acceptance and evolution of emittance along the channel. Conclusions for a possible optimisation of the future muon cooling channel of the Neutrino Factory are presented.

 
WEPE068 Muon Capture in the Front End of the IDS Neutrino Factory 3500
 
  • D.V. Neuffer
    Fermilab, Batavia
  • M. Martini, G. Prior
    CERN, Geneva
  • C.T. Rogers
    STFC/RAL/ASTeC, Chilton, Didcot, Oxon
  • C. Y. Yoshikawa
    Muons, Inc, Batavia
 
 

We discuss the design of the muon capture front end of a neutrino factory and present studies of variations of its components. In the front end, a proton bunch on a target creates secondary pions that drift into a capture transport channel, decaying into muons. A sequence of rf cavities forms the resulting muon beams into strings of bunches of differing energies, aligns the bunches to (nearly) equal central energies, and initiates ionization cooling. The cooling section uses absorber material (reducing the 3-D muon momenta) alternating with rf cavities (restoring longitudinal momentum) within strong focusing magnetic fields. The design is affected by limitations on accelerating gradients within magnetic fields. The effects of gradient limitations are explored, and mitigation strategies are presented. Variations of the ionization cooling and acceleration scenarios and extensions toward use in a muon collider are discussed.

 
WEPE081 Wedge Absorber Design for the Muon Ionisation Cooling Experiment 3536
 
  • P. Snopok, L. Coney
    UCR, Riverside, California
  • A. Jansson
    Fermilab, Batavia
  • C.T. Rogers
    STFC/RAL/ASTeC, Chilton, Didcot, Oxon
 
 

In the Muon Ionization Cooling Experiment (MICE), muons are cooled by ionization cooling. Muons are passed through material, reducing the total momentum of the beam. This results in a decrease in transverse emittance and a slight increase in longitudinal emittance, but overall reduction of 6D beam emittance. In emittance exchange, a dispersive beam is passed through wedge-shaped absorbers. Muons with higher energy pass through more material, resulting in a reduction in longitudinal and transverse emittance. Emittance exchange is a vital technology for a Muon Collider and may be of use for a Neutrino Factory. Two ways to demonstrate emittance exchange in the straight solenoidal lattice of MICE are discussed. One is to let a muon beam pass through a wedge shaped absorber; the input beam distribution must be carefully selected to accommodate chromatic aberrations in the solenoid lattice. Another approach is to use the input beam for MICE without beam selection. In this case no polynomial weighting is involved; however, a more sophisticated shape of the absorber is required to reduce longitudinal emittance.