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DEVELOPMENT OF A COMBINED TR/DR EMITTANCE STATION FOR FUTURE LINEAR COLLIDERS T. Aumeyr 1, M. Bergamaschi 2, E. Bravin 2, P. Karataev 1, R. Kieffer 2,

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Presentation on theme: "DEVELOPMENT OF A COMBINED TR/DR EMITTANCE STATION FOR FUTURE LINEAR COLLIDERS T. Aumeyr 1, M. Bergamaschi 2, E. Bravin 2, P. Karataev 1, R. Kieffer 2,"— Presentation transcript:

1 DEVELOPMENT OF A COMBINED TR/DR EMITTANCE STATION FOR FUTURE LINEAR COLLIDERS T. Aumeyr 1, M. Bergamaschi 2, E. Bravin 2, P. Karataev 1, R. Kieffer 2, T. Lefevre 2, S. Mazzoni 2, N. Terunuma and other members of ATF2 1. John Adams Institute at Royal Holloway, Egham UK 2. CERN European Organisation for Nuclear Research, Geneva, Switzerland 3. KEK: High Energy Accelerator Research Organization, Tsukuba, Japan

2 Personnel & Funding Advanced researchers  P. Karataev, T. Lefevre, E. Bravin and S. Mazzoni Postdoctoral researchers  R. Kieffer and T. Aumeyr PhD student  Michele Bergamaschi Mechanical Engineer  N. Chritin Funding o CERN will fund the hardware o E-JADE EU funded project for EU-JAPAN staff exchange o CLIC-UK Joint collaboration between CERN and UK Universities to develop accelerator instrumentation.

3 Overview Goal: High-resolution measurement system for LCs as an alternative or a supplementary equipment to LW Pushing the limit of OTR high resolution further down to < 100 nm. Developing ODR technology to measure beam size at the micron scale Use the past experience on ODR and OTR measurements at ATF/ATF2 beam lines; Present ODR studies @ CESR-TA (Cornell University, USA) and the corresponding target development; Develop a combined OTR/ODR diagnostic station with R&D capabilities; Future OTR/UVDR tests at ATF2 (Tsukuba, JP)

4 Transition Radiation Transition radiation (TR) appears when a charged particle crosses a boundary between two media with different dielectric constants The resolution is determined by the source dimensions induced by a single particle plus distortion caused by the optical system (diffraction of OTR tails, aberrations)

5 OTR development: Simulation of imaging system 1.Point Spread Function of OTR imaging system: Image generated by a single particle (propagating the OTR E-field in Zemax) 2.Simulation of images obtained for realistic beam size: Sub- micron beam sizes can be measured via the visibility of the PSF

6 Verification of simulation using ZEMAX code TR in the pre-wave zone V. Verzilov, Phys. Lett. A 273 (2000) 135 TR from a tilted target A. Potylitsyn, NIM B 145 (1998) 169

7 Estimation of systematic errors using OTR imaging system 7 Dark area

8 An example of the image measured with linear polarizer and 550±20 nm First Observation: P. Karataev, et al., Physical Review Letters 107, 174801 (2011).

9 Horizontal Projection

10 Vertical Projection

11 Comparison of experimental results with Zemax simulations Investigation of the diffraction effect: OTR PSF size (distance between peaks and FWHM) for different iris diameters

12 Fit function

13 Self-calibration procedure

14

15 Selection of the integration window

16 Comparison of the OTR and Laser-wire measurements

17 Emittance measurement

18 ODR principles Impact parameter, h, – the shortest distance between the target and the particle trajectory - observation wavelength  = E/mc 2 – Lorentz - factor Diffraction radiation (DR) appears when a charged particle moves in the vicinity of a medium

19 ODR principles P. Karataev et al.

20 Typical CCD image measured in the back focal plane of the lens Visibility of the ODR vertical Polarization component depends on the electron beam size

21 ODR at ATF Fit function:

22 Limitations and Sensitivity Photon yield: Optimal Sensitivity: CTF3: CesrTA: CTF3: CesrTA: CLIC:

23 ODR development at CesrTA 0.5 mm slit Image Angular Single particle images Beam size 1.Simulation using Zemax E [GeV]σ H [µm]σ V [µm] 2.132010 2.Beam tests at Cornell Electron Storage Ring since Dec 2012

24 ODR target slit Target Assembly Si target for DR Ultra high precision: 0.1nm roughness, 40nm co-planarity Slit size: 0.5mm SiC mask to suppress background from synchrotron radiation Mask aperture of 1 and 2 mm Small mask aperture leads to stronger interference between the DR of the mask and target 2mm mask aperture1mm mask aperture Asymmetry in the distribution indicates a beam position offset in the slit Target imaging at 600nm

25 ODR @CESR-TA: data analysis 2mm mask, ODR1mm mask, ODRI Angular distribution at 600nm Zemax simulation ODR/ODRI Least Square Fit Analysis Taking into account target co-planarity of 40nm 3 fit parameters: position, size and divergence CESR measured beam parameters ε y [m]σ y (ODR) [μm]σ y ’ (ODR) [μrad] 3.96e-1117.64.08

26 ODR @CESR-TA: new target Beam size measurement through determining the visibility in the ODR angular distribution Improvement: increase the signal to noise ratio by selective darkening of target surface Shadowing leads to light reduction: OK for ring, but critical in linac (number of photons, S/N) Techniques under investigation: Micro sanding of the target (increase diffusion) Carbon deposition by sputtering (absorption)

27 ATF2 ODR experiment (predesign step) Beam BPM Flange (Beam) BPM Flange (Beam) 40 degrees View Port on target (imaging) 90 degrees View Port on target (angular) Camera 45deg View Port Mask Camera 45deg View Port Target laser alignment Mask Actuator s Target Actuator

28 ATF2 ODR experiment (Tank design) BPM Optical table 30cm as Laser Wire

29 Optical system OTR PSF: finding the right lens Limitation of this improvement: aberration & diffraction  need to study further

30 Optical system OTR PSF: comparison between the old and new system Peak separation 4.6μm Peak separation 8.7μm Improved resolution by roughly 50% BUT: lens in vacuum

31 ATF2 OTR/ODR hardware schedule

32  design of vacuum chamber until mid April, then 90 days for procurement  design of mask and target until end of March, then 45 days for procurement  design of optical lines and camera selection until mid March, then 45 days procurement We should be able to install in December 2015 at ATF2, to be discussed now.

33 Shift schedule & Experimental Plan 1 st set for 2015-2016 operation year

34 Shift schedule & Experimental Plan (cont) 1 st set for 2015-2016 operation year

35 Conclusions & Outlook The team is established; Funding for development of hardware and for travel was secured; Simulations are now fully predictive – match theory and measurements; New chamber design is getting finalised; Work on optical read-out system is on-going; A detailed schedule for the project development has been created; Beam optics: only one quadrupole need to be adjusted. To go ahead with manufacturing and purchasing we need a formal OK from the TB. Contribution to ATF operation and goals: Provide a source for bunch length diagnostics with a streak camera; Evaluate the PSF for the current OTRs used at ATF Participate in shifts for machine operation

36 ANY QUESTIONS? Thank you for your attention!

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