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Compton for ILC LCWS2012, UT at Arlington, USA T. Omori (KEK)

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Presentation on theme: "Compton for ILC LCWS2012, UT at Arlington, USA T. Omori (KEK)"— Presentation transcript:

1 Compton for ILC LCWS2012, UT at Arlington, USA T. Omori (KEK)

2 Introduction Polarized e+ by laser Compton Scheme Ee~1GeV for 10MeV gammas easy to control polarization independent source Toward the positron sources (1) Design Study : upgrade from 300 Hz Conventional (2) R/D : Optical cavity at ATF

3 Introduction Polarized e+ by laser Compton Scheme Ee~1GeV for 10MeV gammas easy to control polarization independent source Toward the positron sources (1) Design Study : upgrade from 300 Hz Conventional (2) R/D : Optical cavity at ATF

4 Design Study Upgrade from 300 Hz Conventional e+ source to Compton pol e+ source.

5 Laser Compton e + Source for ILC 2. Ring Base Laser Compton 3. ERL Base Laser Compton 1. Linac Base Laser Compton Storage Ring + Laser Stacking Cavity ( =1  m), and e+ stacking in DR ERL + Laser Stacking Cavity ( =1  m), and e+ stacking in DR Linac + non-stacking Laser Cavity ( =10  m), and No stacking in DR Reminder: We have 3 schemes. T. Omori et al., Nucl. Instr. and Meth. in Phys. Res., A500 (2003) pp 232-252 Proposal V. Yakimenko and I. Pogorersky S. Araki et al., physics/0509016

6 Laser Compton e + Source for ILC 2. Ring Base Laser Compton 3. ERL Base Laser Compton 1. Linac Base Laser Compton Storage Ring + Laser Stacking Cavity ( =1  m), and e+ stacking in DR ERL + Laser Stacking Cavity ( =1  m), and e+ stacking in DR Linac + non-stacking Laser Cavity ( =10  m), and No stacking in DR T. Omori et al., Nucl. Instr. and Meth. in Phys. Res., A500 (2003) pp 232-252 Proposal V. Yakimenko and I. Pogorersky S. Araki et al., physics/0509016 Reminder: We have 3 schemes. (Here we show old designs)

7 20 triplets, rep. = 300 Hz, pulse length ~ 1  s triplet = 3 mini-trains with gaps 44 bunches/mini-train, T b_to_b = 6.15 n sec DR T b_to_b = 6.15 n sec 2640 bunches/train, rep. = 5 Hz T b_to_b = 369 n sec e+ creation go to main linac Time remaining for damping = 137 m sec We create 2640 bunches in 63 m sec Booster Linac 5 GeV NC 300 Hz Drive Linac Several GeV NC 300 Hz Target Amorphous Tungsten Slow Rotation or Pendulum Conventional e+ Source for ILC Normal Conducting Drive and Booster Linacs in 300 Hz operation 2640 bunches 60 mini-trains

8 20 triplets, rep. = 300 Hz, pulse length ~ 1  s triplet = 3 mini-trains with gaps 44 bunches/mini-train, T b_to_b = 6.15 n sec DR T b_to_b = 6.15 n sec 2640 bunches/train, rep. = 5 Hz T b_to_b = 369 n sec e+ creation go to main linac Time remaining for damping = 137 m sec We create 2640 bunches in 63 m sec Booster Linac 5 GeV NC 300 Hz Drive Linac Several GeV NC 300 Hz Target Amorphous Tungsten Slow Rotation or Pendulum Conventional e+ Source for ILC Normal Conducting Drive and Booster Linacs in 300 Hz operation 2640 bunches 60 mini-trains

9 Linac Scheme (Old design) ‏ 4GeV 1A e - beam 30MeV  beam 15MeV e + beam  to e + conv. target ~2 m ► CO 2 laser beam and 4 GeV e-beam produced by linac. ▬ 4GeV 15nC e- beam with 12 ns spacing. ▬ 10 CPs, which stores 10 J CO 2 laser pulse repeated by 83 Mhz cycle. ► 5E+11 γ-ray -> 2E+10 e+ (2% conversion) ► 1.2μs pulse, which contains 100 bunches, are repeated by 150 Hz to generated 3000 bunches within 200ms. ▬ Laser system relies on the commercially available lasers but need R&D for high repetition operation. ▬ Ring cavity with laser amplifier realizes the C0 2 laser pulse train. By V. Yakimenko

10 20 triplets, rep. = 300 Hz, pulse length ~ 1  s triplet = 3 mini-trains with gaps 44 bunches/mini-train, T b_to_b = 6.15 n sec DR T b_to_b = 6.15 n sec 2640 bunches/train, rep. = 5 Hz T b_to_b = 369 n sec e+ creation go to main linac Time remaining for damping = 137 m sec We create 2640 bunches in 63 m sec Booster Linac 5 GeV NC 300 Hz Drive Linac Several GeV NC 300 Hz Target Amorphous Tungsten Slow Rotation or Pendulum Conventional e+ Source for ILC Normal Conducting Drive and Booster Linacs in 300 Hz operation 2640 bunches 60 mini-trains

11 20 triplets, rep. = 300 Hz triplet = 3 mini-trains with gaps 44 bunches/mini-train, T b_to_b = 6.15 n sec DR T b_to_b = 6.15 n sec 2640 bunches/train, rep. = 5 Hz T b_to_b = 369 n sec e+ creation go to main linac Time remaining for damping = 137 m sec We create 2640 bunches in 63 m sec Booster Linac 5 GeV NC 300 Hz Drive Linac Several GeV NC 300 Hz Target CO2 Laser Cavities Linac Compton (NO big change) Normal Conducting Drive and Booster Linacs <-- Reuse 2640 bunches 60 mini-trains Replace target Single Tungsten Target --> CO2 Laser Cavies NO stacking in DR

12 Compton Ring (Old Design)‏ Electron driver:5.3nC, 6.2ns, 1ps, 1.8GeV Laser : 0.6Jx5 CP (optical cavities). By one collision, positron bunch with Ne+:2.0E+8 is generated. 10 bunches are stacked on a same bucket in DR. This process is repeated 10 times with 10ms interval. Finally, Ne+:2E+10 is obtained. 1.8GeV 90 ms (10 ms x 9)

13 ERL scheme (Old Design)‏ Electron is provided by ERL (Energy Recovery Linac). Both advantages (high yield at Linac and high repetition at CR) are compatible in the ERL solution. Continuous stacking the e+ bunches on a same bucket in DR during 100ms, the final intensity is 2E+10 e +. Another 100ms is used for damping. 100 ms

14 20 triplets, rep. = 300 Hz triplet = 3 mini-trains with gaps 44 bunches/mini-train, T b_to_b = 6.15 n sec DR T b_to_b = 6.15 n sec 2640 bunches/train, rep. = 5 Hz T b_to_b = 369 n sec e+ creation go to main linac Time remaining for damping = 137 m sec We create 2640 bunches in 63 m sec Booster Linac 5 GeV NC 300 Hz Drive Linac Several GeV NC 300 Hz Target Amorphous Tungsten Slow Rotation or Pendulum 2640 bunches 60 mini-trains Ring/ERL Compton Normal Conducting Drive < -- Throw away, Booster Linac <-- Reuse 300 Hz Conventional

15 DR T b_to_b = 6.15 n sec 2640 bunches/train, rep. = 5 Hz T b_to_b = 369 n sec go to main linac Time remaining for damping = 137 m sec We throw away this part. Booster Linac 5 GeV NC 300 Hz 2640 bunches 60 mini-trains Ring/ERL Compton Normal Conducting Drive < -- Throw away, Booster Linac <-- Reuse

16 DR T b_to_b = 6.15 n sec 2640 bunches/train, rep. = 5 Hz T b_to_b = 369 n sec go to main linac Time remaining for damping = 137 m sec We create 640 bunches in 63 m sec Booster Linac 5 GeV NC 300 Hz 2640 bunches 60 mini-trains Ring/ERL Compton Normal Conducting Drive < -- Throw away, Booster Linac <-- Reuse We put Compton

17 DR Booster Linac up to 5 GeV duration 1  sec 300 Hz SR 1 GeV Linac Superconducting duration 63 m sec 5 Hz Target Compton Ring or ERL 1.8 GeV T b-to-b = 6.15 ns Stacking Ring 1 GeV C = 260 m No stacking is required in DR 132 bunches are circulated 100 times of stacking for Ring T b-to-b = 6.15 ns Reuse of the linac of the conventional scheme. 2640 bunches are circulated 1000 times of stacking for ERL Ring: T b-to-b = 6.15 ns ERL: T b-to-b = 18.5 ns  -rays e+se+s optical cavities Compton Ring/ERL Compton Normal Conducting Drive < -- Throw away, Booster Linac <-- Reuse

18 DR Booster Linac up to 5 GeV duration 1  sec 300 Hz SR 1 GeV Linac Superconducting duration 63 m sec 5 Hz Target Compton Ring or ERL 1.8 GeV T b-to-b = 6.15 ns Stacking Ring 1 GeV C = 260 m No stacking is required in DR 132 bunches are circulated 100 times of stacking for Ring T b-to-b = 6.15 ns Reuse of the linac of the conventional scheme. 2640 bunches are circulated 1000 times of stacking for ERL Ring: T b-to-b = 6.15 ns ERL: T b-to-b = 18.5 ns  -rays e+se+s optical cavities Ring/ERL Compton Normal Conducting Drive < -- Throw away, Booster Linac <-- Reuse We create 2640 bunches in 63 m sec. We make stacking in the SR. NO stacking in DR. Long pulse (63 ms). Need SC linac.

19 Positrons produced by the polarized gamma-rays are accelerated upto 1 GeV by the superconducting linac then injected into the 1 GeV stacking ring. The linac operates at 5 Hz and has a long duration of 63 m sec. Then the 1 GeV stacking ring with about 260m circumference is employed. In the stacking ring, 132 bunchs are stored with 6.15 ns bunch spacing. The 132 bunches are sent to the booster linac at once by a kicker which pulse length is 1 micro seconds. The booster linac is normal conducting. It has heavy beam loading (3x10 10 positrons/bunch) and operated with about 1μsec pulse duration at 300 Hz. 20 times beam extraction from the stacking. We need 100 times positron bunch stacking in the same bunch in the staking ring. Since the bunch spacing in the Compton ring and in the staking ring is the same, 100 times of stacking need 100 turns in the sacking ring. It takes about 87  s, because the circumference of the ring is 260 m. We take cooling period of 3.2ms after stacking for stable operation of the Compton ring and the stacking ring. Total period of one cycle is 3.3 m sec (300 Hz). 20 times beam extraction takes 63ms. We need 1000 times of the stacking in the same bunch in the stacking ring. The bunch separation in ERL is 18.5 n sec. Therefore, the period of 1000 times positron bunch stacking is about 2.4ms. In a turn of the stacking ring, stacking is performed with three bunch intervals. In the next turn, stacking is not performed in the same bunch, but it is performed in the adjacent bunch which has 6.15-n-sec separation. This means stacking on the same bunch is performed with three turn intervals. The interval makes the stacking easier. Also through the process of the stacking, bunch spacing is changed from 18.5 ns to 6.15 ns. Since stacking takes long time, 2.4 m sec, cooling in the stacking ring is on going simultaneously. Remaining 0.9 m sec is used for additional cooling. Ring/ERL Compton Details (All parameters are tentative and still premature) Ring/ERL Common Details Ring-Compton Details ERL-Compton Details

20 Ring/ERL Compton Timing Chart (All parameters are tentative and still premature)

21 R/D Optical Cavity for Ring/ERL Compton

22 Miyoshi PosiPol2010 dL ∝ /enhancement ~0.01nm for enhancement ~1000 L cav

23 Experiments at the KEK ATF 1.3GeV up to 10 bunches/train Cavity   s

24 Two Prototype Cavities 4-mirror cavity (Inspired by French Activity) 2-mirror cavity high enhancement small spot size complicated control moderate enhancement moderate spot size simple control (Hiroshima / Weseda / Kyoto / IHEP / KEK) demonstration of  ray gen. accum. exp. w/ cavity and acc. intense  ray generation

25 New cavity Installed into the ATF 45.6° 70mm R1 = 99.9% (input), R2 = R3 = R4 = 99.99%

26 Two 4 mirror cavities are at the ATF KEK-Hiroshima installed 2011 LAL-Orsay installed summer 2010 relatively simple control system employs new feed back scheme sophisticated control digital PDH feedback

27 Laser spot size 15  m achieved vertical position[  m]  ray yield [A.U]  =18  m electrons vertical deirection  e =10  m  L =15  m it was 30  m w/ 2 M cavity

28 ATF 2.16MHz ~2.6×10 8 /sec 5bunches/train 2970±20 MeV (the plot ->) ⇒ ~120  s/train  ray Generation / electron e- laser  5.6ns E  [MeV] best record so far ~150  s/train

29 14 th Sep 2012 wave form from detector ◆~ 117/train ⇒ consistent w/ calorimeter measurement ◆ no bunch dependence ( yield is proportional to e- current) e- bunch monitor bunch/bunch measurement

30 14 th Sep 2012 Loss at Mirror 0.25 Watts Loss / Mirror (Very Rough Estimate) New Issue Found 100 PPM Spec. of the Mirror 5 PPM Wrong Fabrication? or We polluted the surface?

31 Status and plan of KEK-Hiroshima cavity 2.6KW stored as of 25 May 2012 – 30  s / bunch (old 2M- Cavity) -> 150  s /train – correspond to 3.3 × 10 8  /s BaF2 detector was employed to observe bunch by bunch generation – Planed to be replaced w/ a Lead glass counter used in TOPAZ barrel cal. at TRISTAN! New Issue Found: Loss at Mirror Plan – more power enhancement 16600 enhancement (finesse 48,000) – digital feedback

32 Summary

33 Summary 1. Design Study: Ways from 300 Hz conventional e + source to Compton pol e + source are presented. (1) Linac Compton : Small modification. Just replace tungsten target by CO2 laser cavities. (2) Ring/ERL Compton : Large modification is required. We add a 1 GeV SC linac (63 ms pulse), a 1 GeV stacking ring, and a Ring/ERL as a driver. 2. R/D: Development of the 4-mirror cavity is on going at KEK for Ring/ERL Compton.

34 Appendix Upgrade from 300 Hz Conventional e+ source to Undulator pol. e+ source

35 e + lineace - lineac e + DR e - DR Undulator e+ source undulator

36 e + lineace - lineac e + DR e - DR 300 Hz Conventional e+ 300 Hz e + source

37 e + lineace - lineac e + DR e - DR 300 Hz Conventional e+ Undulator pol. e+ source 300 Hz e + source

38 e + lineace - lineac e + DR e - DR 300 Hz Conventional e+ Undulator pol. e+ source 300 Hz e + source remove a part of lineac ~ 5 GeV

39 e + lineace - lineac e + DR e - DR 300 Hz Conventional e+ Undulator pol. e+ source 300 Hz e + source put undulator, drift, target,,,, undulator

40 e + lineace - lineac e + DR e - DR 300 Hz Conventional e+ Undulator pol. e+ source 300 Hz e + source put undulator, drift, target,,,, undulator this part?

41 DR T b_to_b = 6.15 n sec Booster Linac 5 GeV NC 300 Hz Drive Linac Several GeV NC 300 Hz Target Amorphous Tungsten Slow Rotation or Pendulum 2640 bunches 60 mini-trains 300 Hz Conventional e+ Undulator pol. e+ source This part will be used as a single-bunch full-charge Keep Alive Source

42 DR T b_to_b = 6.15 n sec Booster Linac 5 GeV NC 300 Hz Drive Linac Several GeV NC 300 Hz Target Amorphous Tungsten Slow Rotation or Pendulum 2640 bunches 60 mini-trains 300 Hz Conventional e+ Undulator pol. e+ source This part will be used as a single-bunch full-charge Keep Alive Source We need the booster linac which has 1 ms pulse length. We need a SC booster linac.

43 DR T b_to_b = 6.15 n sec Booster Linac 5 GeV NC 300 Hz Drive Linac Several GeV NC 300 Hz Target Amorphous Tungsten Slow Rotation or Pendulum 2640 bunches 60 mini-trains 300 Hz Conventional e+ Undulator pol. e+ source This part will will be used as a single-bunch full-charge Keep Alive Source throw away

44 DR T b_to_b = 6.15 n sec Drive Linac Several GeV NC 300 Hz Target Amorphous Tungsten Slow Rotation or Pendulum 2640 bunches 60 mini-trains 300 Hz Conventional e+ Undulator pol. e+ source This part will will be used as a single-bunch full-charge Keep Alive Source

45 e + lineace - lineac e + DR e - DR 300 Hz Conventional e+ Undulator pol. e+ source a part of lineac ~5 GeV becomes the booster

46 DR T b_to_b = 6.15 n sec Booster Linac 5 GeV SC 5 Hz Drive Linac Several GeV NC 300 Hz -- > operate 5 Hz Target Amorphous Tungsten Slow Rotation or Pendulum 2640 bunches 60 mini-trains 300 Hz Conventional e+ Undulator pol. e+ source This part will will be used as a single-bunch full-charge Keep Alive Source put a 5 GeV SC linac which comes from the end of the main linac

47 DR T b_to_b = 6.15 n sec Booster Linac 5 GeV SC 5 Hz Drive Linac Several GeV NC 300 Hz -- > operate 5 Hz Target 2640 bunches 60 mini-trains 300 Hz Conventional e+ Undulator pol. e+ source gamma-ray from undurator Target

48 DR T b_to_b = 6.15 n sec Booster Linac 5 GeV SC 300 Hz Drive Linac Several GeV NC 300 Hz -- > operate 5 Hz 2640 bunches 60 mini-trains 300 Hz Conventional e+ Undulator pol. e+ source Keep Alive Source gamma-ray e + lineace - lineacundulator

49 300 Hz Conventional e+ Undulator pol. e+ source Pros. No big additional investment. We can reuse removed e- linac for the e+ booster. Cons. Decrease E cm dE(e-) = - 5 GeV (remove e- linac) - 3 GeV (undulator) dE cm = - 16 GeV (We don't want asymmetric collision)

50 Summary

51 Summary 1. Design Study: Ways from 300 Hz conventional e + source to Compton pol e + source are presented. (1) Linac Compton : Small modification. Just replace tungsten target by CO2 laser cavities. (2) Ring/ERL Compton : Large modification is required. We add a 1 GeV SC linac (63 ms pulse), a 1 GeV stacking ring, and a Ring/ERL as a driver. 2. R/D: Development of the 4-mirror cavity is on going at KEK for Ring/ERL Compton. 3. Appendix: A way from 300 Hz conventional e + source to undulator pol e + source is presented.

52 Backup Slides

53 (For ERL, in each turn stacking are performed with three bunch intervals. This makes the stacking easier and changes bunch spacing from 18.5 ns to 6.15 ns.)

54 Laser Compton e + Source for ILC 1. Ring Base Laser Compton 2. ERL Base Laser Compton 3. Linac Base Laser Compton Storage Ring + Laser Stacking Cavity ( =1  m), and e+ stacking in DR ERL + Laser Stacking Cavity ( =1  m), and e+ stacking in DR Linac + non-stacking Laser Cavity ( =10  m), and No stacking in DR We have 3 schemes. T. Omori et al., Nucl. Instr. and Meth. in Phys. Res., A500 (2003) pp 232-252 Proposal V. Yakimenko and I. Pogorersky S. Araki et al., physics/0509016

55 SC Linac 1.8 GeV Laser Optical Cavities Photon Conversion Target Capture System To Positron Liniac RF Gun Dump Electron Storage Ring 1.8 GeV 1.8 GeV booster Ring scheme and ERL scheme are SIMILAR Ring Scheme ERL scheme

56 Compton Ring (1)‏ Inverse Compton scattering between electron stored in a ring (CR) and laser light stored in optical cavities. Energy spread of the electron beam is increased by the scattering. 10 ms interval for the beam cooling. 100 times stacking in a same bucket of DR makes the required bunch intensity.

57 We should go to 3D 4 mirror ring cavity to get small sport size 2 mirrors is not stable for small spot size α 2d 4M has astigmatism 3D (or twisted) 4M ring cavity

58 Brief History 2007 2 Mirror cavities installed –  kW  rays generate 2010 French 4 Mirror cavity installed –  rays confirmed 2011 earthquake – No major damage to our equipment. – beam back in June 2011 2011 KEK-Hiroshima 4 mirror cavity installed –  rays confirmed Reported FJPPL2010 Annecy

59 Installation of KEK-Hiroshima 4M-cavity

60 3 Dimensional 4 Mirror Cavity Resonates only for circular polarization – geometric phase due to twisted pass – cavity only resonates with circular polarization – usable for pol. switching circumference of the cavity left handed right handed transmitted light

61 Configration of test bed

62 calculation of spot size w/ test bench geometry minor axis major axis spot size  (  m) spot size is not sufficiently small with test bench geometry L(mm) L

63 new geometry

64 expected spot size w/ new geometry 421424426428 0 20 40 spot size  (  m) L(mm) laser spot size of 15  m is expected with new geometry Before optimization After optimization

65 Cavity length feedback with 3D feature + = 3D4M cavity resonate only with circularly polarized lasers differential signal for feedback cavity length must be L = n  with very high precision (for enhancement of 1900 dL<< 87pm while L = 1.64m)

66 右円偏光 左円偏光 蓄積強度 Laser Power 2.6kW Time Jitter = 8.0ps 14 th Sep 2012 Stored Laser Power in the cavity

67 Right pol Left pol Sotred power Laser Power 2.6kW (1850 enhancement) Time Jitter = 8.0ps 14 th Sep 2012 Stored Laser Power in the cavity Stored Power [w] FWHM: 110pm 4pm

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