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Outline

Title
Abstract
Introduction 1.TECHNICAL Considerations
Overview of Components
Bending Magnet Design
Discussion
Lattice Design
Detector Background
Muon Decay Background
Muon Halo Background
Electron Pair Background
Conclusion
References
All Topics
Physics
Mathematical Physics

Muon collider design

Profile image of Adi KitAdi Kit

1996, Nuclear Physics B-proceedings Supplements

Abstract
sparkles

AI

Muon Colliders offer significant technical and physics advantages, serving as complementary options to hadron and electron colliders. This paper presents designs for two high luminosity muon colliders at 4 TeV and 0.5 TeV, as well as a lower luminosity 0.5 TeV demonstration machine. Key technical challenges are addressed, including muon production, cooling, and the impacts of muon decay on collider operations and detector backgrounds.

References (75)

  1. R. Palmer 1,2 , A. Sessler 3 , A. Skrinsky 4 , A. Tollestrup 5 , A. Baltz 1 , S. Caspi 3 , P. Chen 2 , W-H. Cheng 3 , Y. Cho 6 , D. Cline 7 , E. Courant 1 , R. Fernow 1 , J. Gallardo 1 , A. Garren 3,7 , H. Gordon 1 , M. Green 3 , R. Gupta 1 , A. Hershcovitch 1 , C. Johnstone 5 , S. Kahn 1 , H. Kirk 1 , T. Kycia 1 , Y. Lee 1 , D. Lissauer 1 , A. Luccio 1 , A. McInturff 3 , F. Mills 5 , N. Mokhov 5 , G. Morgan 1 , D. Neuffer 5 , K-Y. Ng 5 , R. Noble 5 , J. Norem 6 , B. Norum 8 , K. Oide 9 , Z. Parsa 1 , V. Polychronakos 1 , M. Popovic 5 , P. Rehak 1 , T. Roser 1 , R. Rossmanith 10 , R. Scanlan 3 , L. Schachinger 3 , G. Silvestrov 4 , I. Stumer 1 , D. Summers 11 , M. Syphers 1 , H. Takahashi 1 , Y. Torun 1,12 , D. Trbojevic 1 , W. Turner 3 , A. Van Ginneken 5 , T. Vsevolozhskaya 4 , R. Weggel 13 , E. Willen 1 , W. Willis 1,14 , D. Winn 15 , J. Wurtele 16 , Y. Zhao 1
  2. BINP, RU-630090 Novosibirsk, Russia
  3. KEK, Tsukuba-shi, Ibaraki-Ken 305, Japan
  4. DESY, Hamburg, Germany 11) University of Mississippi, Oxford, MS 38677, USA
  5. SUNY, Stony Brook, NY 11974, USA
  6. UC Berkeley, Berkeley, CA 94720-7300, USA REFERENCES
  7. E. A. Perevedentsev and A. N. Skrinsky, Proc. 12th Int. Conf. on High Energy Accelerators, F. T. Cole and R. Donaldson, Eds., (1983) 485; A. N. Skrinsky and V.V. Parkhomchuk, Sov. J. of Nucl. Physics 12, (1981) 3; Early Concepts for µ + µ -Colliders and High Energy µ Storage Rings, Physics Potential & Development of µ + µ -Colliders. 2 nd Workshop, Sausalito, CA, Ed. D. Cline, AIP Press, Woodbury, New York, (1995).
  8. D. Neuffer, Colliding Muon Beams at 90 GeV , Fermilab Physics Note FN- 319 (1979), unpublished; D. Neuffer, Particle Accelerators, 14, (1983) 75; D. Neuffer, Proc. 12th Int. Conf. on High Energy Accelerators, F. T. Cole and R. Donaldson, Eds., 481 (1983).
  9. Proceedings of the Mini-Workshop on µ + µ -Colliders: Particle Physics and Design, Napa CA, Nucl Inst. and Meth., A350 (1994) ; Proceedings of the Muon Collider Workshop, February 22, 1993, Los Alamos National Laboratory Report LA-UR-93-866 (1993) and Physics Potential & Development of µ + µ - Colliders 2 nd Workshop, Sausalito, CA, Ed. D. Cline, AIP Press, Woodbury, New York, (1995).
  10. Transparencies at the 2 + 2 TeV µ + µ -Collider Collaboration Meeting, Feb 6- 8, 1995, BNL, compiled by Juan C. Gallardo; transparencies at the 2 + 2 TeV µ + µ -Collider Collaboration Meeting, July 11-13, 1995, FERMILAB, compiled by Robert Noble; Proceedings of the 9th Advanced ICFA Beam Dynamics Workshop, Ed. J. C. Gallardo, AIP Press, to be published.
  11. Overall Parameters and Construction Techniques Working Group report, Pro- ceedings of the Fifth International Workshop on Next-Generation Linear Col- liders, Oct 13-21, 1993, Slac-436, pp.428.
  12. D. V. Neuffer and R. B. Palmer, Proc. European Particle Acc. Conf., London (1994);
  13. M. Tigner, in Advanced Accelerator Concepts, Port Jefferson, NY 1992, AIP Conf. Proc. 279, 1 (1993).
  14. R. B. Palmer et al., Monte Carlo Simulations of Muon Production, Physics Potential & Development of µ + µ -Colliders 2 nd Workshop, Sausalito, CA, Ed. D. Cline, AIP Press, Woodbury, New York, pp. 108 (1995).
  15. T. Roser, AGS Performance and Upgrades: A Possible Proton Driver for a Muon Collider, Proceedings of the 9th Advanced ICFA Beam Dynamics Work- shop, Ed. J. C. Gallardo, AIP Press, to be published.
  16. Y. Cho, et al., A 10-GeV, 5-MeV Proton Source for a Pulsed Spallation Source, Proc. of the 13th Meeting of the Int'l Collaboration on Advanced Neutron Sources, PSI Villigen, Oct. 11-14 (1995);
  17. Y. Cho, et al., A 10-GeV, 5-MeV Proton Source for a Muon-Muon Collider, Proceedings of the 9th Advanced ICFA Beam Dynamics Workshop, Ed. J. C. Gallardo, AIP Press, to be pub- lished.
  18. F. Mills, et al., presentation at the 9th Advanced ICFA Beam Dynamics Work- shop, unpublished; see also second reference in [4].
  19. T. Roser and J. Norem, private communication.
  20. D. Kahana, et al., Proceedings of Heavy Ion Physics at the AGS-HIPAGS '93, Ed. G. S. Stephans, S. G. Steadman and W. E. Kehoe (1993);
  21. D. Kahana and Y. Torun, Analysis of Pion Production Data from E-802 at 14.6 GeV/c using ARC, BNL Report # 61983 (1995).
  22. N. V. Mokhov, The MARS Code System User's Guide, version 13(95), Fermilab-FN-628 (1995).
  23. J. Ranft, DPMJET Code System (1995).
  24. N. Mokhov, R. Noble and A. Van Ginneken, Target and Collection Optimization for Muon Colliders, Proceedings of the 9th Advanced ICFA Beam Dynamics Workshop, Ed. J. C. Gallardo, AIP Press, to be published.
  25. R. Weggel, private communication; Physics Today, pp. 21-22, Dec. (1994).
  26. R. Chehab, J. Math. Phys. 5, (1978) 19.
  27. F. Chen, Introduction to Plasma Physics, Plenum, New York, pp. 23-26 (9174);
  28. T. Tajima, Computational Plasma Physics: With Applications to Fusion and Astrophysics, Addison-Wesley Publishing Co., New York, pp. 281-282 (1989).
  29. A. A. Mikhailichenko and M. S. Zolotorev, Phys. Rev. Lett. 71, (1993) 4146;
  30. M. S. Zolotorev and A. A. Zholents, SLAC-PUB-6476 (1994).
  31. A. Hershcovitch, Brookhaven National Report AGS/AD/Tech. Note No. 413 (1995).
  32. Z. Huang, P. Chen and R. Ruth, SLAC-PUB-6745, Proc. Workshop on Ad- vanced Accelerator Concepts, Lake Geneva, WI , June (1994);
  33. P. Sandler, A. Bogacz and D. Cline, Muon Cooling and Acceleration Experiment Using Muon Sources at Triumf, Physics Potential & Development of µ + µ -Colliders 2 nd Workshop, Sausalito, CA, Ed. D. Cline, AIP Press, Woodbury, New York, pp. 146 (1995).
  34. D. Neuffer, in Advanced Accel- erator Concepts, AIP Conf. Proc. 156, 201 (1987); see also [1].
  35. U. Fano, Ann. Rev. Nucl. Sci. 13, 1 (1963).
  36. G. Silvestrov, Proceedings of the Muon Collider Workshop, February 22, 1993, Los Alamos National Laboratory Report LA-UR-93-866 (1993);
  37. B. Bayanov, J. Petrov, G. Silvestrov, J. MacLachlan, and G. Nicholls, Nucl. Inst. and Meth. 190, (1981) 9; Colin D. Johnson, Hyperfine Interactions, 44 (1988) 21;
  38. M. D. Church and J. P. Marriner, Annu. Rev. Nucl. Sci. 43 (1993) 253.
  39. G. Silvestrov, Lithium Lenses for Muon Colliders, Proceedings of the 9th Ad- vanced ICFA Beam Dynamics Workshop, Ed. J. C. Gallardo, AIP Press, to be published.
  40. D. Neuffer, Acceleration to Collisions for the µ + µ -Collider, Proceedings of the 9th Advanced ICFA Beam Dynamics Workshop, Ed. J. C. Gallardo, AIP Press, to be published.
  41. D. Summers, presentation at the 9th Advanced ICFA Beam Dynamics Work- shop, unpublished.
  42. I. Stumer, presentation at the BNL-LBL-FNAL Collaboration Meeting, Feb 1996, BNL, unpublished.
  43. S.Y. Lee, K.-Y. Ng and D. Trbojevic, FNAL Report FN595 (1992);
  44. Phys. Rev. E48, (1993) 3040; D. Trbojevic, et al., Design of the Muon Collider Isochronous Storage Ring Lattice, Micro-Bunches Workshop, BNL Oct. (1995), to be published.
  45. K. Oide, private communication.
  46. K. L. Brown and J. Spencer, SLAC-PUB-2678 (1981) presented at the Parti- cle Accelerator Conf., Washington, (1981) and K.L. Brown, SLAC-PUB-4811 (1988), Proc. Capri Workshop, June 1988 and J.J. Murray, K. L. Brown and T.H. Fieguth, Particle Accelerator Conf., Washington, 1987; Bruce Dunham and Olivier Napoly, FFADA, Final Focus. Automatic Design and Analysis, CERN Report CLIC Note 222, (1994);
  47. Olivier Napoly, it CLIC Final Focus Sys- tem: Upgraded Version with Increased Bandwidth and Error Analysis, CERN Report CLIC Note 227, (1994).
  48. J. C. Gallardo and R. B. Palmer, Final Focus System for a Muon Collider: A Test Model, BNL #, CAP 138-MUON-96R (1996), this proceedings.
  49. A. Garren, et al., Design of the Muon Collider Lattice: Present Status, this proceedings.
  50. K. Oide, SLAC-PUB-4953 (1989);
  51. J. Irwin, SLAC-PUB-6197 and LBL-33276, Particle Accelerator Conf.,Washington, DC, May (1993);
  52. R. Brinkmann, Opti- mization of a Final Focus System for Large Momentum Bandwidth, DESY-M- 90/14 (1990).
  53. M. Syphers, private communication; K.-Y. Ng, Beam Stability Issues in a Quasi-Isochronous Muon Collider, Proceedings of the 9th Advanced ICFA Beam Dynamics Workshop, Ed. J. C. Gallardo, AIP Press, to be published.
  54. K.Y. Ng, Beam Stability Issues in a Quasi-Isochronous Muon Collider, Pro- ceedings of the 9th Advanced ICFA Beam Dynamics Workshop, Ed. J. C. Gallardo, AIP Press, to be published.
  55. W.-H. Cheng, A.M. Sessler, and J.S. Wurtele, Studies of Collective Instabili- ties, in Muon Collider Rings, Proceedings of the 9th Advanced ICFA Beam Dynamics Workshop, Ed. J. C. Gallardo, AIP Press, to be published.
  56. V. Balakin, A. Novokhatski and V. Smirnov, Proc. 12th Int. Conf. on High Energy Accel., Batavia, IL, 1983, ed. F.T. Cole, Batavia: Fermi Natl. Accel. Lab. (1983), p. 119.
  57. A. Chao, Physics of Collective Beam Instabilities in High Energy Accelerators, John Wiley & Sons, Inc, New York (1993).
  58. W.-H. Cheng, private communication.
  59. P. Chen and K. Yokoya, Phys. Rev. D38 987 (1988);
  60. P. Chen., SLAC-PUB- 4823 (1987);
  61. Proc. Part. Accel. School, Batavia, IL, 1987; AIP Conf. Proc. 184: 633 (1987).
  62. K. Assamagan, et al., Phys Lett. B335, 231 (1994);
  63. E. P. Wigner, Ann. Math. 40, 194 (1939) and Rev. Mod. Phys., 29, 255 (1957).
  64. B. Norum and R. Rossmanith, Polarized Beams in a Muon Collider, this pro- ceedings.
  65. G. W. Foster and N. V. Mokhov, Backgrounds and Detector Performance at 2 + 2 TeV µ + µ -Collider, Physics Potential & Development of µ + µ -Colliders 2 nd Workshop, Sausalito, CA, Ed. D. Cline, AIP Press, Woodbury, New York, pp. 178 (1995).
  66. I. Stumer, private communication and presentation at the BNL-LBL-FNAL Collaboration Meeting, Feb. 1996, unpublished.
  67. Geant Manual, Cern Program Library V. 3.21, Geneva, Switzerland, 1993.
  68. N. V. Mokhov and S. I. Striganov, Simulation of Background in Detectors and Energy Diposition in Superconducting Magnets at µ + µ -Colliders, Fermilab- Conf-96/011, Proceedings of the 9th Advanced ICFA Beam Dynamics Work- shop, Ed. J. C. Gallardo, AIP Press, to be published.
  69. P. Chen, presentation at the 9th Advanced ICFA Beam Dynamics Workshop and this conference, unpublished.
  70. L. D. Landau and E. M. Lifshitz, Phys. Zs. Sowjetunion 6, 244 (1934);
  71. V. M. Budnev, I. F. Ginzburg, G. V. Medelin and V. G. Serbo, Phys Rep., 15C, 181 (1975).
  72. P. Chen, presentation at the 9th Advanced ICFA Beam Dynamics Workshop and this conference, unpublished.
  73. I. Ginzburg, private communication and this proceedings.
  74. P. Chen and N. Kroll, private communication.
  75. G. V. Stupakov and P. Chen, Plasma Suppression of Beam-Beam Interaction in Circular Colliders, SLAC Report: SLAC-PUB-95-7084 (1995)

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