Status of SuperKEKB Design: Lattice and IR

Transcription

1 Status of SuperKEKB Design: Lattice and IR Y. Ohnishi July 7, rd Open Mee8ng of the Belle II collabora8on Tanabata : Festival of the Weaver? KEK

2 Contents Nano-beam scheme: Design concept Machine parameters Lattice and IR

3 Design concept Luminosity is determined by 3 parameters in principle.

4 Collision scheme High current scheme * σ x σ z Nano beam scheme σz σx * L 2φ * σ z = σ x φ σ * x = σ z φ Half crossing angle: φ Head-on frame (rotation and Lorentz boost) L = σ x * φ Total projected cross section is equal for each other.

5 High Current Nano Beam Bunch length requirement : Hourglass requirement : σ z < σ * x φ φ 0 β y * σ z ( ) σ > σ * x z φ β * y σ * x φ Luminosity : L N +N σ x * σ y * L N +N φσ z σ y * Beam-beam parameter : ξ y N + σ x * β y * ε y ξ y N + φσ z * β y ε y

6 Strategy of Nano beam Smaller σ y * provides higher luminosity. Smaller β y * provides smaller σ y *, however longer σ z is OK. (less HOM, no CSR) Hourglass (H.G) condition requires smaller σ x *, namely smaller β x * is necessary. Smaller beam-beam parameter is preferable, so ε y should be smaller in proportional to β y * Small β x *, β y * and small emittance is required. Lattice design

7 Requirement: 8x10 35 cm -2 s -1 Nano beam scheme LER/HER ε x = 2.8 nm / 2.0 nm β x* = 17.8 mm / 25 mm β * y = 0.26 / 0.26 mm ξ y = ~ KEKB

8 Machine parameters Tenta8ve parameters: LER HER Emi1ance ε x nm Coupling ε y /ε x % Horizontal beta at IP β * x mm Ver@cal beta at IP β * y mm Horizontal beam size σ * x µm Ver@cal beam size σ * y µm Bunch length σ z 5 mm Half crossing angle φ 30 mrad Beam Energy E Beam Current I A Number of bunches n b 2252 Beam beam parameter ξy Luminosity L 8x10 35 (8.5x10 35 with CW) cm 2 s 1 * Luminosity is obtained from beam beam simula8ons.

9 Lattice design

10 LER Longer bends HER Increase number of arc cells

11 Separated final quads Closer to IP

12 Local chromaticity correction No/small emittance generation

13 Summary of items Low emixance LER Longer bends 0.89 m to 4 m long HER Increase number of arc cells Smaller dispersion in bends 28 cells to 44 cells Low beta at IP Separated final quads. Closer to IP Superconduc@ng or permanent magnets Local chroma8city correc8on (LCC) (to get large DA) KEKB LER type Chicane like (reverse bends) Geometrical flexibility Emi1ance is generated. ILC/SuperB type (modified to SuperKEKB) Bending angle is necessary (no reverse bends). Emi1ance can be ignored.

14 One of constraints is tunnel geometry.

15 TSUKUBA IR To Oho To Nikko LER/HER has an incident angle of -10/+50 mrad for GX-axis. LCCinner wall LCC Nano-LER HER LCC Nano-HER LCC Tsukuba LER outer wall

16 In case of HER, large incident angle(50 mrad) makes large bending angle at LCC. Consequently, large dispersion at LCC for HER. Then, chromaticity correction can be done with keeping dynamic aperture.

17 On the other hand, LER can use KEKB-LER type for LCC since wiggler sections can control emittance. Chicane type LCC is almost straight beam line from a global point of view although large dispersion can be made at LCC.

18 Beam axis and Solenoid axis KEKB LER GY *GY is parallel to OHO/NIKKO straight GX is perpendicular to GY. KEKB HER 4.55 mrad mrad GX SuperKEKB LER SuperKEKB HER GY 50 mrad = mrad New BELLE Solenoid? 10 mrad GX BELLE Solenoid=LER What is the Belle solenoid axis? Solenoid axis is: (a) LER axis > mrad (b) ½ of finite crossing angle > mrad (c) or no solu8on to rotate BELLE

19 LER IR optics β x */β y *=17.8 mm/0.26 mm LCC LCC u c = 0.44 kev

20 HER IR optics β x */β y *=25 mm/0.26 mm m M LCCY = LCC m M LCCY = LCC Y. OHNISHI / KEK

21 HER arc to IR optics Arc Normal cell LCC(Vertical) LCC(Horizontal) Y. OHNISHI / KEK

22 LER whole ring C = m (same as KEKB-LER) Y. OHNISHI / KEK

23 HER whole ring C = m (same as KEKB-HER) #arc cells 40 Y. OHNISHI / KEK

24 IR magnets (Preliminary)

25 Dynamic aperture

26 HER dynamic Aperture (stored) β x */β y *=25 mm/0.26 mm NO ERROR 2Jy/2Jx= 1.8% n e = 6.17x10 10 τ touschek = 17 min x/σ x Δp/p 0

27 HER dynamic aperture (injection) β x */β y *=25 mm/0.26 mm NO ERROR x/σ x Injection Aperture: (synchrotron injection) 2J x = 3.7x10-9 m (1.23x10-9 m in injector) 2J z =0.5%+0.15% 2Jy/2Jx= 4% Injection Aperture: (betatron injection) 2J x = 5x10-7 m 2J y =2x10-8 m 2J z =0.15%(σ δ =0.05% in injector) Δp/p 0

28 LER dynamic aperture (injection & stored) Injection Aperture: (betatron injection) 2J x = 5x10-7 m 2J y =2x10-8 m 2J z =0.25% Injection Aperture: (synchrotron injection) 2J x = 1.2x10-8 m (4x10-9 m in injector) 2J z =0.5%+0.25% Touschek lifetime ~400 sec n p = 10.7x10 10 k = 0.74 %

29 Synchrotron injection septum wall (w = 5 mm) injected beam stored beam injection kicker injection kicker *This scheme is applied in LEP. 1) Energy of injected beam is shifted by δ 0, then an injection orbit is adjusted to be a closed orbit of the ring. (X 0,X 0 )=(η,η )δ 0 2) The coherent betatron oscillation due to the injection error should be zero since the betatron oscillation is transformed to the synchrotron oscillation. X0 = 2.5 σ inj + 3 σ ring + w = 6~6.5 mm η = 1.28 m (LER) / 1.2 m (HER) for δ 0 = 0.5 %

30 To make this possible, the injection point will be moved from the FUJI straight section to the arc section. -> Remodel the BT lines

31 Good quality of injected beam is quite necessary. e- low emittance RF gun and e+ DR

32 IR magnet configuration: Permanent magnet + S.C. corrector (alternative) Final focus quadrupoles(qc1) can be closer to IP than S.C. magnets only. This makes larger dynamic aperture.

33 QC1P/E(Permanent Magnet) Preliminary Correction S.C. magnet IP 2009/7/2 IR / N. Ohuch

34 Summary The lattice of Nano beam scheme is still being developed. Dynamic aperture is not enough so far for injection/touschek lifetime. It strongly depends on IR magnet configuration. We are considering both permanent and superconducting magnets.

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36 Appendix

37 LER Arc Cell L= 0.89 m ε x (nm) 4 m α p ε x = 8.8 nm α p = 3.3x10-4 ε x = 2 nm α p = 4.4x10-4

38 HER arc cell 2.5π non-interleaved sextupole chromaticity correction -I Y. OHNISHI / KEK

39 HER arc cell #magnets increases by 60% Emittance (nm) Momentum Compaction

40 QCS1P mm [ 370mm] QCS1E mm [ 500mm] IP QCS1P mm (910mm : 5/1 op@cs ) QCS1E mm (1460 mm) 2009/7/2 IR

41 LER IR optics β x */β y *=17.8 mm/0.26 mm LCC LCC