T. Suehara, H. Yoda, T. Sanuki, Univ. of Tokyo, T. Kume, Y. Honda, T. Tauchi, High Energy Accelerator Research Organization (KEK) ATF2-IN2P3-KEK kick-off.

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Presentation transcript:

T. Suehara, H. Yoda, T. Sanuki, Univ. of Tokyo, T. Kume, Y. Honda, T. Tauchi, High Energy Accelerator Research Organization (KEK) ATF2-IN2P3-KEK kick-off meeting (Oct. 10, 2006) Shintake monitor status

ATF2 Shintake-monitor group Students –T. Suehara (Univ. of Tokyo, D2), Optics (main table, laser table) Overall design,etc. –H. Yoda (Univ. of Tokyo, M1) Gamma detector Staffs –T. Sanuki (Univ. of Tokyo), Advisor (ATF2, overall) –T. Kume (KEK), Optics support (fringe stabilization etc.) –Y. Honda (KEK), Support (optics etc.) –T. Tauchi (KEK) Advisor (ATF2, overall)

Progress from status reported in 2 nd ATF2 project meeting(1/2) Phase control/scan of interference fringes ( by Suehara) –Principle of refection type delay line was confirmed by using PZT stage. –Possibility of PLZT is also considered. Precise phase monitor (Kume) –Phase monitor not affected by light intensity change was designed and prepared for experimental confirmation. Off-axis real time phase monitor (Suehara) –Fringes during operation are to be monitored by using off-axis monitor. –Correlation between two phase monitors and Off-axis) is prepared for experiment and going to be observed and confirmed by using two sets of monitoring system.

Progress from status reported in 2 nd ATF2 project meeting(2/2) Optical axis stabilizing system against long laser transfer line is now being prepared for operation. (Suehara) Gamma detector (Suehara, Yoda) –Multi layer inorganic scintillator is estimated to be more promising compared to multi cherenkov detector through simulation. –Detecting system adopting scintillator is under designing.

Phase detection using optical microscope CCD with fringe magnify optics (using microscope lens) > 1mm fringe (6 ゜,30 ゜ setup)

Experimental setup for observing interference fringes by using microscope Laser specifications wavelength532 nm power20 mW (CW) line width6 MHz beam diameter0.7 mm beam divergence<1.3 mrad stability±3 % modeTEM00 M ^2 1.2 Set on the optical table with air suspension made of granite to isolate floor vibration. Covered to prevent air flow

Experimental setup and Observed fringes Angle between two beam a=25 deg, Wavelength =532 nm, Fringe pitch  =1250 nm Laser Microscope(×100)

Online phase monitor For online monitoring, we must use off-axis monitor (we cannot put phase detector at IP during ATF2 operation !) Correlation between IP and off-axis monitor must be checked. Phase will be stabilized by phase scanner (delay line) using off-axis phase monitor data.

9/12 Phase delays (shifters) for phase control Reflection type (by changing relative distance d between the two mirror sets) ->Position resolution of  d=0.37 nm is required for 0.74 nm of resolution Transmission type ( by rotating angle  of glass plate) ->Angular resolution of  =~3 min (=8.7*10 -4 rad) is required for 0.74 nm of resolution ->h=~12  m for 90 deg of fringe phase change (in case plate thickness: t=3 mm, refractive index: n=1.5)

10/12 Durable and precise phase detection (Not to affected by intensity change of LASER light source) Difference of  the 2 interfered light intensities s:  I i0 -I ip Canceling E 01 and E 02 【 assamptions 】 1.Equal transmission/reflection ratio of half mirror :HM, 2.Equal sensitivity of photo diodes:PD i0 and PD ip

Gamma detector (1) Multi material cherenkov detector High energy subtraction by forward Cherenkov detector ○ Insensitive to background shower statistics ×Number of emission photons is low.

Gamma detector (2) Multi layer inorganic scintillator Using difference of shower development for energy separation ○ Easy to make, sufficient light emission ×Vulnerable to shower development fluctuation Detector schematics Simulated energy deposit