Target and Absorbers L2 Manager: K McDonald, Princeton U March xx, 2013 Presenter’s Name | DOE Mini-Review of MAP (FNAL, March 4-6, 2013)1 Mission Target:

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Presentation transcript:

Target and Absorbers L2 Manager: K McDonald, Princeton U March xx, 2013 Presenter’s Name | DOE Mini-Review of MAP (FNAL, March 4-6, 2013)1 Mission Target: Maximum production of  ± of energies ~ MeV from a 4-MW proton beam (E ~ 8 GeV). Both signs needed simultaneously at a Muon Collider. Absorbers: Absorb the 4-MW beam power inside the target system. Absorb muon energy as a step in the process of ionization cooling.

Target and Absorbers L2 Manager: K McDonald, Princeton U March xx, 2013 Presenter’s Name | DOE Mini-Review of MAP (FNAL, March 4-6, 2013)2 Key Technical Issues Ta rget : Free liquid-metal-jet target inside a high-field superconducting solenoid magnet Backup (not actively considered): solid target in toroidal horn (2 needed for Muon Collider). Absorbers: A bsorb primary proton beam in liquid-metal pool. Absorb secondary particles in He-gas-cooled tungsten beads – inside solenoid magnets. Low-Z solid/liquid muon absorbers under study in MICE (D. Kaplan) High-pressure H 2 -gas absorbers under study by Muons Inc (R. Johnson).

Target and Absorbers, II Targetry Activities March xx, 2013 Presenter’s Name | DOE Mini-Review of MAP (FNAL, March 4-6, 2013)3 1.Simulation of beam-jet interaction in a magnetic field (R. Samulyak, T. Guo). 2.Simulation of turbulent flow inside, and out of, the nozzle (F. Ladiende, Y. Zhan). 3.Simulation of particle production vs. beam & target parameters (X. Ding). 4.Simulation of the effect of the magnetic configuration on particle production (H. Sayed). 5.Simulation of secondary-energy deposition in the target system (N. Souchlas). 6.Design of the magnets and shielding for the target system (R.J. Weggel). 7.Design of the mercury-handling system (V.B. Graves). 8.Coordination of the above, and interface with other MC/NF Systems (J.S. Berg, H.G. Kirk, K.T. McDonald). The above activities are projected to continue well beyond FY15. Past activities included a proof-of-principle demonstration of a free mercury jet in a 15-T magnetic field in an intense proton beam (CERN MERIT experiment). Timely to initiate hardware tests of splash mitigation in a mercury pool beam dump.