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P I T Z Photo Injector Test Facility Zeuthen Design consideration of the RF deflector to optimize the photo injector at PITZ S.Korepanov.

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Presentation on theme: "P I T Z Photo Injector Test Facility Zeuthen Design consideration of the RF deflector to optimize the photo injector at PITZ S.Korepanov."— Presentation transcript:

1 P I T Z Photo Injector Test Facility Zeuthen Design consideration of the RF deflector to optimize the photo injector at PITZ S.Korepanov

2 P I T Z Photo Injector Test Facility Zeuthen The prospect diagnostic complex for the beam phase analysis Longitudinal resolution length in the tomography module: At the Screen4 ~ 0.15 mm (0.5 ps) – 55 slices At the Screen1 ~ 0.35 mm (1.1 ps) – 23 slices Vertical screen size ~ 30 mm

3 P I T Z Photo Injector Test Facility Zeuthen RF Deflection Classic cavity “Paramonov” cavity Travelling wave cavity “LOLA” Length ~ 0.7 m f = 1.3 GHz a)D.Alesini, C.Vaccarezza, “Longitudinal and transverse phase space characterization”, SPARC-RF-03/003, INFN/LNF, Frascati, 2003 b)V.Paramonov, et. al. “Effrctive standing- wave RF structure for charged-particle deflector”, LINAC, 2006 c)O.H.Altenmueller, et.al., “Investigations of traveling – wave separator s for the Stanford two-mile linear accelerator”, The rev. of Sci. instr., Vol.35(4), 1964 a) b) c)

4 P I T Z Photo Injector Test Facility Zeuthen a) b) c) Pz, eV/c Red line – initial distribution Blue line – distribution after: Classic cavity “Paramonov” cavity Traveling wave cavity (LOLA) Maximum resolution ~ 25 keV/c (~10 -3 )  32 MeV/c

5 P I T Z Photo Injector Test Facility Zeuthen Results of the simulations: For the all kind of the cavities the beam emittance has changed from 0.96 mm mrad to ~1.02 mm mrad Steady wave cavity requires less RF power. Travelling wave cavity has small field filling time. => Possibility to analyze a single bunch in the train. Classic cavity“Paramonov” cavityTravelling wave cavity TomographyDispersiveTomographyDispersiveTomographyDispersive Distance, m2-4.26 6 6 V , MV0.85-1.80.6 0.85-1.8 0.6 0.85-1.8 0.6 Q21000 15000 19000 P RF, MWup to 10.12 up to 0.17 0.02 up to 9.1 1.01 Field build up,  s ~20 ~0.2

6 P I T Z Photo Injector Test Facility Zeuthen Summary: The three different deflector were analyzed in complex with the tomography module and the dispersive section. The longitudinal resolution length for the beam analysis in the tomography module is 0.35mm (0.5 ps). Resolution of the dispersive section is limited by 25 keV Transverse emittance distortion by the deflector and the kicker is about a few %. To do: Try to reduce the longitudinal momentum distortion in the deflector (D.Alesini). More detail cavity analysis. Design the real geometry (coupler, load). (D.Alesini)

7 P I T Z Photo Injector Test Facility Zeuthen The prospect diagnostic complex for the beam phase analysis Longitudinal resolution length in the tomography module: At the Screen4 ~ 0.15 mm (0.5 ps) – 55 slices At the Screen1 ~ 0.35 mm (1.1 ps) – 23 slices

8 P I T Z Photo Injector Test Facility Zeuthen Kicker ( TESLA damping ring kicker ) Free aperture 50mm x 50 mm Length 300 mm Field rise/fall (10%-90%) ~5 ns Pulse length 30 ns Repetition rate 2 MHz (~100 pulses), 5 Hz Deflection for 30 MeV up to 6.6 mrad Frank Obier (DESY -MIN-) For PITZ2 beam: L =1m – distance between kicker and the screen Deflection angle ~2 mrad Off axis ~ 2 mm  Pz ~ 1% Pz =>  x rms ~ 10  m X rms ~ 120  m

9 P I T Z Photo Injector Test Facility Zeuthen Flange fields effect (estimation) beam By(x=0,y,z) The beam is deflected by By. Inhomogeneity ~ 0.4%

10 P I T Z Photo Injector Test Facility Zeuthen a) b) c) The gap in the initial distribution - 0.15 mm Red line – initial distribution Blue line – distribution after: Classic cavity “Paramonov” cavity Traveling wave cavity (LOLA)

11 P I T Z Photo Injector Test Facility Zeuthen Diagnostic complex for beam phase space analysis Longitudinal slice transverse emittance measurements DC + Tomography module Longitudinal phase space analysis DC + Dispersive arm Q Q Q Q Q Q QQ Q Q Screen1 DC Screen2 Screen3Screen4 ~ 6 m matching tomography module Dispersive arm Screen 7.5 m D.J.Holder, et. al., “A phase space tomography diagnostic for PITZ”, EPAC2006, Edinburgh, UK

12 P I T Z Photo Injector Test Facility Zeuthen average long. momentum32 MeV/c min. norm. emittance (rms) ~ 1  mm mrad transverse beam size on the screen in the tomography module, rms (full) ~ 0.12 (0.7) mm full longitudinal beam size8 mm (27 ps) pulse frequency1-9 MHz repetition rate10 Hz Beam parameters for the simulations:

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