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Compton Experiment at ATF Compton Meeting at LAL Orsey 2-Dec-2008 Tsunehiko OMORI (KEK) with many thanks to Compton collaborators.

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Presentation on theme: "Compton Experiment at ATF Compton Meeting at LAL Orsey 2-Dec-2008 Tsunehiko OMORI (KEK) with many thanks to Compton collaborators."— Presentation transcript:

1 Compton Experiment at ATF Compton Meeting at LAL Orsey 2-Dec-2008 Tsunehiko OMORI (KEK) with many thanks to Compton collaborators

2 Experimental R/D in ATF. Make a fist prototype 2-mirror cavity Put it in ATF ring Hiroshima-Waseda-Kyoto-IHEP-KEK L cav = 420 mm

3 Laser Stacking Optical Cavity in Vacuum Chamber

4 Summer 2007: Assembling the Optical Cavity

5 October 2007: Install the 2-mirror cavity into ATF-DR

6 Before Summer

7 DAQ Schematic Continued to change the length of the external cavity. Only picked up the data when the cavity was resonated. 2.16MH z - e cavity Could pass Comparator Gate was opened for 100ns. T = 463ns PD

8 The appearance of light resonance signal Reflected light Transmitted light In this time, the optical cavity was resonated state Transmitted light Mirror reflectivity : 99.6% Mode locked laser (Photo diode) PD time (ms) Continued to change the length of the external cavity. 1ms

9 Gamma Energy distribution 2 This graph shows the appearance of gamma energy distribution. one of gamma had 16~28 MeV energy. 1 gamma 2 gamma

10 The number of gamma 1 bunch : experiment  ~3.3 simulated by CAIN   ~ 4.5 20 bunches : experiment  ~3.1 simulated by CAIN  ~ 20 In the case of 1 bunch, the number of gamma seems to consist comparing our experiment data with estimate by CAIN. However, the data of 20bunches were inconsistent.The reason of this,there was a possibility that not every electron bunches were collided. We estimated the number of gamma to use a simulation software “CAIN”. bunch distance : 2.8 ns Mirror reflectivity : 99.6% 1 - 0.996 transmitted power stack power=

11 Present Status

12 L cav = n  L cav = m L laser Laser freq = Ring RF Feedback to Achieve 3 Conditions

13 PIDHV Phase Detector Ring RF HV BPF DC + keep resonance PID sync. to Acc. Piezo PD Ref-light Stacking Cavity Laser laser light pulses offset Normal Solution QPD

14 DC + Phase Detector BPF Piezo PD Ref-light Stacking Cavity Laser PIDHV QPD PIDHV Ring RF keep resonance sync. to Acc. laser light pulses offset (Sakaue) Cross-feedback Solution offset

15 PIDHV Phase Detector Ring RF HV BPF DC + keep resonance PID sync. to Acc. Piezo PD Ref-light Stacking Cavity Laser laser light pulses offset Normal Solution QPD can be SLOW must be FAST

16 PIDHV Phase Detector Ring RF HV BPF DC + keep resonance PID sync. to Acc. small mirror FAST large mirror SLOW Piezo PD Ref-light Stacking Cavity Laser laser light pulses offset Normal Solution QPD can be SLOW must be FAST

17 DC + Phase Detector BPF Piezo PD Ref-light Stacking Cavity Laser PIDHV QPD PIDHV Ring RF keep resonance sync. to Acc. laser light pulses offset (Sakaue) Cross-feedback Solution offset can be SLOW must be FAST small mirror FAST large mirror SLOW

18 Optical cavity condition In summer time, we succeeded to keep condition of optical cavity timing lock and locking at resonance point. Last week beam time, Optical cavity was to keep condition timing lock and locking at resonance point. Transmitted light Locking at resonance Timing locked Timing

19 Energy Distribution single-bunch operation

20 Best collision point data in 1 bunch and 2 bunches 1 bunch2 bunches Scanning to Horizontal position Scanning to Timing After that, we tried to take 3 bunches data. However, gamma detector was broken. Now, gamma detector is recovered.

21 Rough consistency check  ÷ the number of electron ÷ stack power 1 bunch 1.715×10E+8 2 bunches  1 bunch data and 2 bunches data seem to consistent This week We try 10-bunch and 20-bunch operation The number of  : 6.2 × 2.16×10E+6 [1/second] Simulated by Cain 1bunch  : 5.7 2 bunches :6.7

22 Summary

23 1. Success : Resonance Feedback + Phase Lock on Acc RF Before Summer No feedback Trigger : Acc + Transmitted Light Present Normal Feedback ---> Cross-feedback Resonance Feedback + Phase Lock on ACC RF Trigger : Acc 2. Collision Experiment on going 5 gamma / crossing (single-bunch op.) 6 gamma / crossing (two-bunch op.) Consistent: Experiment CAIN simulation Consistent: single-bunch two-bunch This week : collision in 10-bunch and 20-bunch op.

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