.... Fundamental Concepts of Particle Accelerators V : Future of the High Energy Accelerators VI : References Koji TAKATA KEK koji.takata@kek.jp http://research.kek.jp/people/takata/home.html Accelerator Course, Sokendai Second Term, JFY2011 Oct. 25, 2012
Contents 1 Dawn of Particle Accelerator Technology 2 High-Energy Beam Dynamics (1) 3 High-Beam Dynamics (2) 4 RF Technology 5 Future of the High Energy Accelerators ERL: Energy Recovery Linac LC : Linear Collider µ-µ Collider Laser-Plasma Wave Accelerator Livingston Chart 6 References Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 2 / 11
ERL: Energy Recovery Linac (1) KEK-PF-ERL : one of the KEK future plans Linac: 1.3 GHz Superconducting type Ultrashort (0.1 ps 3 ps) electron bunches are generated by the electron gun with a photo-cathode irradiated by laser pulses. 3 GeV 3GeV ERL rf /2 path-length changer 6 (7) GeV Al 2 O 3 (00030) T=0.997 R 1 =0.96 100m undulator Al 2 O 3 (00030) T=0.997 R 1 =0.92 T 1 =0.032 143KeV X-rays XFEL-O in 2nd stage Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 3 / 11
ERL: Energy Recovery Linac (2) Basic Features The injection linac accelerates a train of ultrashort ( ps) electron bunches to a few GeV. The bunches make just one turn around the ring emitting ultrashort SR lights and return to the linac. In the linac, they lose their energy by emitting microwave power, which contributes to the acceleration of the next train of electron bunches. The ultrashort SR lights are used for observation of fast transient phenomena in condensed matters. In the conventional SR rings, the bunch length is too long ( µs) due to the quantum nature of SR photons. Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 4 / 11
LC : e + e Linear Collider Basic Features of the Linear Collider Aiming at the center-of-mass energy around 1 TeV or higher. The main accelerator should be of the linac type because of the SR s γ 4 energy loss in the ring accelerators. The accelerator complex for electrons and that for positrons are almost the same except for the particle source. The beam emittance should be extremely small to achieve a moderate luminosity at the collision. Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 5 / 11
Muon Collider Since the muon mass is 206.7 times larger than the electron and the γ 4 issue is greatly mitigated, a ring collider scheme is still acceptable, and its site scale becomes much smaller than that for a linear collider. The transverse emittance of the muon beam just after the target is so large that R&D of efficient beam-cooling system is the most critical issue. A continuous RF acceleration during the cooling is necessary to cope with the short life time of the muon: τ µ = 2.2 µs. Linac Proton Linacs Synchrotron Target Solenoid Li/Be Absorbers Collider Recirculation Linac Linac cf. R. Palmer and R. Fernow: An Overview of Muon Colliders, Beam Dynamics Newsletter 55 (ICFA, Aug. 2011) p.22. Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 6 / 11
Laser-Plasma Wave Accelerator (1) cf. C. Joshi and T. Katsouleas : Physics Today, June 2003, p.47. Four possible ways to generate plasma waves (relativistic electron density waves) At present, longitudinal gradients of the order of 200 GeV/m have been achieved in a length of a few mm. Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 7 / 11
Laser-Plasma Wave Accelerator (2) cf. C. Joshi and T. Katsouleas : Physics Today, June 2003, p.47. Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 8 / 11
Livingston Chart Accelerator Energy (ev) 10 17 10 16 10 15 10 14 10 13 10 12 10 11 10 10 10 9 10 8 10 7 10 6 1PeV 1TeV 1GeV Collider (Equivalent Energy) Proton Synchrotron Electron Linac Electron Synchrotron Synchro-cyclotron Proton Linac 1MeV Electrostatic Accelerator Betatron Cyclotron DC Generator 1930 1940 1950 1960 1970 1980 1990 2000 2010 M. S. Livingston & J. P. Blewett: Particle Accelerators, p.6, MacGraw Hill, 1962. For the colliders, the energy is converted to that for their equivalent fixed target system. Maximum energies ever achieved Electron synchrotron: 2 100 GeV (2000, CERN LEP) Proton synchrotron: 2 7 TeV (2010, CERN LHC) http://lhc.web.cern.ch/lhc/ Target energy for ILC (International e + e Linear Collider) 2 500 GeV? (2025 or later?) Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 9 / 11
References (1) Segrè, E. : From X-rays to Quarks (W. H. Freeman and Company, 1980). Historical introduction to the evolution of high energy physics and accelerator science Chao, A. W. and Tigner, M. (ed.) : Handbook of Accelerator Physics and Engineering (World Scientific, 1999). Compact encyclopedia of accelerator science and technology Edwards, D. A. and Syphers, M. J. : An Introduction to the Physics of High Energy Accelerators (Wiley, 1993). Concise text book on accelerator physics Wiedemann, H. : Particle Accelerator Physics I, II (Springer, 1999). Text book on accelerator physics Courant, E. D. and Snyder, H. S.: Annals of Physics, 3 (1958) p.1. A classical paper on the theory of the strong focusing Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 10 / 11
References (2) Schwinger, J. : Physical Review, 75 (1949) p.1912. A classical paper on the theory of the synchrotron radiation Gilmour, A. S. : Microwave Tubes (Artech House, 1986). Text book on the electron tube technology Padamsee, H., Knobloch, J. and Hays, T. : RF Superconductivity for Accelerators (John Wiley & Sons, 1998). Text book on RF superconductivity and its application to energy accelerators Koji Takata (KEK) Fund. Conc. Part. Acc. 4 Acc. Course, Oct. 2012 11 / 11