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SuperB Damping Rings M. Biagini, LNF-INFN P. Raimondi, SLAC/INFN A. Wolski, Cockroft Institute, UK SuperB III Workshop, SLAC, 14-16 June 2006.

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Presentation on theme: "SuperB Damping Rings M. Biagini, LNF-INFN P. Raimondi, SLAC/INFN A. Wolski, Cockroft Institute, UK SuperB III Workshop, SLAC, 14-16 June 2006."— Presentation transcript:

1 SuperB Damping Rings M. Biagini, LNF-INFN P. Raimondi, SLAC/INFN A. Wolski, Cockroft Institute, UK SuperB III Workshop, SLAC, 14-16 June 2006

2 SuperB Rings SuperB rings have same characteristics as the ILC Damping Rings, that is: –Short damping times (  s < 10 sec) –Small emittance (  x < 1 nm) –Low emittance coupling (0.25 %) Natural candidate is OCS lattice from ILCDR Baseline Design

3 OCS lattice 10-fold symmetry with 10 long straight sections 8 straight sections contain wigglers and RF cavities, the other 2 can accommodate tune-adjustment sections and injection Arc cell is a TME (Theoretical Minimum Emittance), 40 m long, with 72 dipoles 5.6 m long with low (0.2 T) field Wigglers are SC, 1.6 T field, 10.4 m long in each section

4 ILCDR Parameters OCS

5 SuperB Rings Parameters From document presented at CERN Strategy Group and INFN Roadmap: www.pi.infn.it/SuperB/ (March 2006)

6 SuperB Schematic Layout Beams are vertically separated here Dogleg FF -FF e + DR

7 Rings have asymmetric energies of 4 and 7 GeV OCS lattice was scaled from 5 GeV to 4 and 7 6.1 Km, 3.2 Km and 2.2 Km long rings were studied Emittances and damping times were kept similar for each configuration Lattice symmetry was respected Fewer and lower field wigglers used (pm ?) Longer dipoles were used, when needed Preliminary Final Focus (A. Seryi) included

8 OCS lattice: 6.1 Km ILC Damping Rings, 8 wiggler sections 4 GeV: same wiggler sections (8) and field, same bend length 7 GeV: same wiggler field, less wiggler sections (6), double bend length 6.1 Km lattice

9 4 GeV, 6.1 Km Wiggler cell FODO cell 135°/90° FODO cells 8 wiggler cells, 1.6 T

10 135°/90° FODO cells 6 wiggler cells, 1.6 T FODO cell Wiggler cell Double length bends 7 GeV, 6.1 Km

11 Universita’ di Roma “ Tor Vergata” green area - the campus Frascati INFN & ENEA Laboratories

12 3.2 Km Rings The OCS lattice has many free drifts and a relatively low number of quadrupoles and bends  quite easy to shorten the ring Quadrupole strengths and beta peaks are higher though Arc needs higher dispersion for better chromaticity correction  in progress

13 7 GeV ring, 3 Km

14 4 GeV ring, 3 Km

15 Possible issues of shorter rings Same as ILCDR, that is: –Dynamic aperture –HER e-cloud instability  new electrodes ? –LER Intra Beam Scattering –Fast Ion Instability  gaps in train

16 Intra Beam Scattering DR Baseline Configuration Document, Feb. 06  x growth  z growth  y growth  E growth OCS lattice, 5 GeV

17

18 2.2 Km Rings A first solution was found by: –Shortening drifts in dispersion suppressors –Eliminating some of the FODO cells –Shortening wiggler-free sections in 7 GeV ring –Shortening long drift sections in 4 GeV Preliminary, can be easily improved

19 7 GeV ring, 2.2 Km

20 4 GeV ring, 2.2 Km

21 A. Seryi Final Focus (March 06)   x * = 17.6 mm  y * = 80 

22 2.2 Km ring with FF  Matching section to FF

23 Chromatic functions W x, W y and 2 nd order dispersion in FF

24 Comparison of Ring Parameters 4 GeV7 GeV C (m)6114.3251.2230.6114.3251.2230. B w (T)1.61.4 1.61.4 L bend (m)5.6 6.7211.210.66.72 N. bends96 10096 100 B bend (T)0.0780.1550.1250.1360.1440.218 Uo (MeV/turn)5.74.43.510.76.47. N. wigg. cells888644  x (ms)28.819.817.26.24.14.5  s (ms)14.410.8.61312.7.25  x (nm)0.50.380.370.50.5650.64 EE 1.1x10 -3 10 -3 1.3x10 -3 1.32x10 -3 1.35x10 -3 I beam (A)2.5 1.4 P beam (MW)14.11.8.815.9.9.8 P wall (MW) (50% eff) 43.53028 ---

25 Dynamic aperture Preliminary dynamic aperture calculations for the 3 Km ring @ 7 GeV with FF have been performed by A. Wolski Studied tune behavior vs energy deviation First dynamic aperture & frequency map analysis Tunes not optimized  needs work Sextupoles not optimized  needs work

26 Chromaticity vs energy deviation for ideal 3 Km lattice without FF x tune y tune A. Wolski

27 Chromaticity vs energy deviation for ideal 3 Km lattice with FF x tune y tune A. Wolski Energy acceptance between 1% and 2%

28 Dynamic aperture for “ideal” lattice with FF (3 Km, 7 GeV) A. Wolski Frequency map analysis, sextupoles tuned for 0 chromaticity Coordinate space Tune space 3 sigma Coupling resonance

29 Conclusions 3 rings with asymmetric energies have been studied by scaling the ILCDR OCS lattice Final Focus has been inserted in all They all look reasonable A lot of work is still needed: –Optimization of arc cell –Dynamic aperture optimization –Dependence of vertical emittance from errors –Collective effects Beam instabilities will be different due to different energies and need to be studied especially for the LER There is full synergy with ILCDR as requested

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