1 / 17

6D MANX A Muon Cooling Demonstration Experiment; How it might fit within MICE.

6D MANX A Muon Cooling Demonstration Experiment; How it might fit within MICE. Tom Roberts Muons, Inc. http://muonsinc.com. Muons, Inc. is pursuing new ideas about muon cooling:. High pressure gas in RF cavities Emittance exchange in a continuous absorber

woods
Download Presentation

6D MANX A Muon Cooling Demonstration Experiment; How it might fit within MICE.

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. 6D MANXA Muon Cooling Demonstration Experiment;How it might fit within MICE. Tom Roberts Muons, Inc. http://muonsinc.com MICE CM15

  2. Muons, Inc. is pursuing new ideas about muon cooling: • High pressure gas in RF cavities • Emittance exchange in a continuous absorber • Continuous absorber in a helical magnetic channel • Momentum-dependent helical cooling channel • Parametric resonance ionization cooling • Reverse emittance exchange • Simultaneous muon capture, phase rotation, and cooling • High-energy muon bunch coalescing (NF and MC synthesis) • Very high field magnetic channels • Synergies among refrigeration, a cryogenic absorber, cryogenic magnets, and simultaneous beam and thermal cooling This presentation discusses the genesis of 6D MANX, and how it might fit in with MICE. (Items in green lead to 6D MANX) MICE CM15

  3. First New Idea: High Pressure Gas in an RF Cavity • Measurements show we can achieve high RF gradients with high pressure H2 gas. • Recent measurements show that unlike vacuum cavities,the high gradient shows nosignificant decrease in amagnetic field up to 3 Tesla(and probably higher) • With high-pressure gas inthe RF cavities, we startedthinking about continuousabsorbers…. MICE CM15

  4. Second Idea: Emittance exchange in a continuous absorber • In a magnetic field andcontinuous absorber,there can be emittanceexchange that permitslongitudinal cooling • Ultimately that permitsthe use of higher-frequency RF, with highergradients • But the real advantagehappens in a helicalcooling channel…. MICE CM15

  5. Third Idea: The Helical Cooling Channel (HCC) • In a HCC, high-momentum particlesnaturally have longer path lengths, providing emittanceexchange in a continuous absorber • By adjusting the balance ofsolenoid and helical fields, the desired ratio oftransverse and longitudinalcooling can be varied withinrather wide limits • Integrated RF cavities keepthe momentum ~constant • But it is difficult to put largeRF cavities inside thehelical magnets…. blue=μ+; red=RF cavities; white=reference The RF cavities are centered along the reference helix. (solenoid and helical magnets not shown, they are outside the RF cavities) MICE CM15

  6. Fourth Idea: Momentum-Dependent Helical Cooling Channel • Omitting the RF cavities, the particles naturally lose energy (momentum) in the continuous absorber • Scale the magnetic fieldswith the momentum loss • The result is a considerablyless complex system whichretains its exceptionalcooling properties • This is the basic device wewant to demonstrate in6D MANX MICE CM15

  7. The Helical Cooling Channel (HCC)Magnetic Fields Solenoid (Field into the paper) The Helical Dipole and Helical Quadrupole Magnetic Fields. The beam acceptance is 45° into the page, in the light blue circle. Both figures rotate clockwise around the solenoid center as Z increases, thus forming a helix. (This has been extensively analyzed analytically, and there are numerous papers discussing this at http://muonsinc.com) MICE CM15

  8. A 4-meter LHe HCC has Exceptional Cooling • Continuous liquid He absorber • Far above equilibrium emittance,so Liquid He is appropriate • Transverse cooling factor ~1.5 • Longitudinal cooling factor ~1.5 • 6D cooling factor is 3.8 • Maximum field ~5.5 Tesla MICE CM15

  9. In early May we submitted a Letter of Intent describing 6D MANX to the Fermilab Director Letter of Intent to propose a SIX-DIMENSIONAL MUON BEAM COOLING EXPERIMENT FOR FERMILAB Ramesh Gupta, Erich Willen Brookhaven National Accelerator Laboratory Charles Ankenbrandt, Emanuela Barzi, Alan Bross, Ivan Gonin, Stephen Geer, Vladimir Kashikhin, Valeri Lebedev, David Neuffer, Milorad Popovic, Vladimir Shiltsev, Alvin Tollestrup, Daniele Turrioni, Victor Yarba, Katsuya Yonehara, Alexander Zlobin Fermi National Accelerator Laboratory Daniel Kaplan, Linda Spentzouris Illinois Institute of Technology Alex Bogacz, Kevin Beard, Yu-Chiu Chao, Yaroslav Derbenev, Robert Rimmer Thomas Jefferson National Accelerator Facility Mohammad Alsharo’a, Mary Anne Cummings, Pierrick Hanlet, Robert Hartline, Rolland Johnson*, Stephen Kahn, Moyses Kuchnir, David Newsham, Kevin Paul, Thomas Roberts Muons, Inc. (Gail Hanson, UCR added since the initial Presentation) [Full text at http://muonsinc.com] MICE CM15

  10. … and then, a Miracle Occurred … • Dr. Oddone jumped in with both feet: • He requested an immediate meeting with Muons, Inc. to discuss it • During the meeting he expressed considerable interest and a willingness to support this effort, suggesting a goal of a Muon Collider with an energy of about 1.5 TeV in the center-of-mass • He disclosed that the DoE has earmarked $5M of Fermilab’s 2007 budget for Advanced Accelerator R&D (AARD), and stated quite strongly that he did not want to lose those funds from the lab • During the meeting he asked his staff to develop an AARD proposal to the DoE to design and build this magnet • And to top it off, we have learned that Fermilab’s “spare” superconductor (from the SSC) might well be sufficient to construct the solenoid part of the HCC magnet MICE CM15

  11. …“Be careful what you wish for”… • We now have an extraordinary opportunity to work with Fermilab to obtain the primary and most expensive component of 6D MANX, in the 2007-2008(?) timeframe • To make this happen, we must be very busy this summer: • Support the writing of Fermilab’s AARD proposal (due ~September) • Prepare a complete proposal for the 6D MANX experiment • Remarkably, we have Phase I funding to do just that! • Continue to perform on our already committed program • Including Phase I funding for enhancing G4beamline MICE CM15

  12. 6D MANX is just like MICE, only different • Similar goals… • Demonstrate concepts and technology for muon cooling • Similar approach… • Single-particle tracking to demonstrate emittance reduction and validate simulations • Similar beam… • Few hundred μ per second, 200-300 MeV/c • Similar needs… • Cryogenics, hall space, magnet power, tracking, PID, DAQ, analysis, … MICE CM15

  13. 6D MANX is just like MICE, only different • Similar, but somewhat different purposes • MICE: demonstrate technology for transverse cooling for a more affordable Neutrino Factory • 6D MANX: create a Muon Collider revolution for HEP • Energy frontier machine • Precision machine • Our intent is to use extreme cooling so ILC RF structures can be used • Rather different cooling channels • Quite different current status • MICE is of course an approved and established experiment • All major decisions have been made • Engineering has begun, much of it is nearing completion • Some construction is imminent • 6D MANX is just starting up • We need to form a collaboration, put organization in place, etc. • We still have major decisions to make • Engineering is in its infancy MICE CM15

  14. 0th Guess at a Configuration – 1 Brute force – put a Helical Cooling Channel between the two MICE spectrometers MICE CM15

  15. 0th Guess at a Configuration – 2 • This is a simplistic and incomplete configuration: • Orient the HCC so the reference track of the spectrometer enters along the reference helix • No matching was done; the currents for the matching coils were simply left at their MICE Stage VI values • The exit of this particular HCC is not horizontal, so no attempt was made to get into the second spectrometer • With a fat beam input to the first spectrometer, 99% of particles that exit the spectrometer also exit the HCC • This merely shows the acceptance of the HCC is larger than the acceptance of the spectrometer • We had to start somewhere. But we clearly need to be a lot more sophisticated! MICE CM15

  16. More Sophisticated Approaches • Our Phase I funding is to solve the matching problem to the HCC, perform initial simulations and design, and begin to prepare a proposal • Efforts on the matching problem have just begun • Ideas, programs, proofs of principle exist • See Derbenev, Lebedev, Bogacz, Burov,… • There are matching techniques developed for flat beams • Electron cooling in the recycler (solenoid  Quads) • A coaxial design appears possible using variations on the MANX idea itself • First approach: turn helical dipole on adiabatically • Initial example takes 15 m for 300 MeV/c – clearly needs work! MICE CM15

  17. Summary • 6D MANX is currently on an exciting trajectory leading toward realization • The synergies between 6D MANX and MICE are enormous There are many ways to work together! … Let us discuss how … MICE CM15

More Related