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Quartz preparation (quality check and prototype status). BPAC, 12th Nov. 2011. Y. Horii (Nagoya University). Introduction. The quartz bars must transmit Cherenkov photons over long optical length with a number of internal reflections . In this talk, we show
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Quartz preparation(quality check and prototype status) BPAC, 12th Nov. 2011 Y. Horii (Nagoya University)
Introduction • The quartz bars must transmit Cherenkov photons over long optical length with a number of internal reflections. • In this talk, we show • optical qualities of the bars and • status of preparing prototype for the beam test. Examples of photon paths inprototype for beam test in 2010.
Optical properties • Number of photons • Resolution of Cherenkov angle naively depends on square root of number of photons. • Require to retain 80% after bulk transmittance andreflections. • Photon-path shifts • Resolution of Cherenkov angledepends on photon-path shifts. • Require the shift to be < 0.5 mradafter reflectionsand by striae.
Quartz bars Suprasil-P710 polished by Okamoto Co. Corning 7980 0Dpolished by Zygo Co. 131 x 45 x 2 cm2 120 x 45 x 2 cm2 Highest striaegradein MIL-G-174 standard Highest striaegradein ISO 10110-4 standard Better flatness Better squareness in general
Equipments for checking quality of bars Laser: Wavelength = 405 nm(typical for TOP). Prism splitter and reference PDto calibrate fluctuations. Position adjustable on motorizedstages with a precision of O(mm). CCD: 4.4 x 4.4 mm2/pixel. 1600 x 1200 pixels. Position adjustable onmotorized stages witha precision of O(mm). Photodiode: efficiency stable forat least 6x 6 mm2.
Bulk transmittance Requirement: > 98%/m. Bulk transmittance tobtained using intensities I0 and I1 measured by PD and reflectances R0 and R1 calculated. y z x 7 x 5 incident points. Suprasil-P710: Ave. = 99.44%/m Max. = 99.57%/m Min. = 99.27%/m Corning 7980 0D: Ave. = 99.35%/m Max. = 99.50%/m Min. = 99.25%/m (Error of individual measurement: ±0.17%/m.) For both bars, enough bulk transmittance for all incident points.
Internal surface reflectance Requirement: > 99.90%. • Measure the reflectance for several angles of reflections in 56-70°. • For both bars, enough reflectance for interested angles. y z Surface reflectance aobtained using intensities I0 and I1 measured by PD,reflectances R0 and R1 calculated,and the exponential of bulk transmittance. N: number of bouncesL/b: length/thickness of bar L: coefficient of bulk transmittance Suprasil-P710: Max. = 99.98% Min. = 99.92% Corning 7980 0D: Max. = 99.97% Min. = 99.92% (Error: ±0.02%.)
Possible effect of striae • Data taken by CCD. • Bitmap (histogram) fitted with 2-D Gauss + 2-D linear. • Scan the positions of laser/CCD simultaneously in y direction. y z Scan. y x Means and widths of 2-D Gauss in interest.
Possible effect of striae Requirement: path shift < 0.5 mrad. Mean in y direction most significantly fluctuates for both bars. Suprasil-P710 polished by Okamoto Corning 7980 0D polished by Zygo y > 20 mm:laser through air. Displacement btwy < 20 and > 20 mm:due to deviation ofincident angle from 0. Path shift within ±0.15 mrad Path shift within ±0.33 mrad These path shifts can be explained by surface non-flatness. Effects of striae smaller.
Possible effect of striae • Other checks: • No larger path shifts for other x positions. • No larger path shifts for another incident angle of 30°. • No larger path shifts for scan of laser/CCD in x direction. • Finer scan for estimating finer periodic structure of striae: Larger variation for y width.But still can be explainedby surface non-flatness.No significant effect for PID.
Strategy of the gluing • Put the Okamoto bar downstream of photon path since squareness of Okamoto bar is worse. • Use glue of NOA63 for bar-bar joint (higher viscosity). • Use glue of NBA107 for mirror (temporary since mirror is smaller).
Control of angles and positions • Relative angle of bars • Adjust using micrometerheads. • Measure using autocollimator. • Relative position of bars • Adjust using polyacetal headsand plungers. • Measure using laser sensor. Precision = ±0.01 mrad, requirement = ±0.2 mrad. Precision = ±5 mm, requirement = ±100 mm.
Gluing Glue goes down. Takes ~1 hour. Put glue using dispenser (head is soft). Cured by UV light. Takes <5 hours.
Check after the gluing • Quartz-quartz joint • No significant bubbles are seen. • Angles and displacements satisfy the requirements. • Angles of S4/C and S1/E = 0.03 and 0.10 mrad, respectively. • Displacements at S4/C, S3/D, and S1/E = 90, 60, and 40 mm, respectively. • Quartz-mirror joint • Small amount of bubbles (photon loss < 0.1%). • Angles and displacements satisfy the requirements. • Angle = 0.03 mrad. • Displacement = 50 mm. Requirement for angle: 0.2 mrad. Requirement for displacement: 100 mm.
Summary • Optical qualities checked. • Bulk transmittance, surface reflectance, and effect of striaefortwo bars of Suprasil-P710/Okamoto and Corning 7980 0D/Zygo. • All results satisfy the requirements. • Glue of bars and mirror. • Prototype ready for beam test in Dec. 2011. • Method of glue ready for productions for Belle II.
Quartz bars Suprasil-P710 polished by Okamoto Co. Corning 7980 0D polished by Zygo Co.
Laser Photodiode CCD
Bulk transmittance Suprasil-P710 Corning 7980 0D
Internal surface reflectance Requirement: > 99.90%.
Roughness • Roughness and reflectance are related by a scalar scattering theory: d: RMS of roughness q: angle of reflectance l: wavelength of laser Okamoto bar:d = (12 ± 4) Å Zygo bar:d = (17 ± 4) Å
Possible effect of striae Requirement: path shift < 0.5 mrad. Suprasil-P710 polished by Okamoto Corning 7980 0Dpolished by Zygo Results corresponds to path shift < 0.3 mrad. Can be explained by surface non-flatness.
Surface non-flatness and path shifts y measured by Zygo blue z green S6 S5 Quartz Laser CCD 0.1-0.3mrad shift can be generated.
Quality check of the mirror • In addition to the bars, we do several checks for the mirror. Bulk transmittance Reflectance at quartz-Al Result = (99.20 ± 0.38)% Result = (88.5 ± 0.2)% Safely large. Will require better value for TOP.
Jig for gluing Micrometers Quartz bar (Placed on polyacetal balls.) Vinyl chloride plate (Placed for avoiding quartz-Al contact.) Upper Al plate (Position adjustable using micrometers.)(Surface flatness < 100 mm.) Lower Al plate Rails. (Position adjustable on the rails.)
Lower Al plate Overall configuration (one bar) Upper Al plateand micrometer-head
Polyacetal head to adjustthe position of the bar. Bar, polyacetal balls, and plastic plate. Plunger to keepthe position of the bar.
Flatness of the bars • Flatness of the bars after adjusting the angles and positions is measured by using autocollimator. • The flatness is safely nice for the gluing. Suprasil-P710 Corning 7980