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Scintillating screens issues at the European XFEL

Scintillating screens issues at the European XFEL. Quenching effects at the XFEL screen stations Charging effects at the of-axis XFEL screen stations. A. Novokshonov , G. Kube , M. Scholz , S. Liu, B. Beutner , S. Strokov. Quenching effects at XFEL. Scintillator based monitors at XFEL.

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Scintillating screens issues at the European XFEL

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  1. Scintillating screens issues at the European XFEL Quenching effects at the XFEL screen stations Charging effects at the of-axis XFEL screen stations A. Novokshonov, G. Kube, M. Scholz, S. Liu, B. Beutner, S. Strokov

  2. Quenching effects at XFEL

  3. Scintillator based monitors at XFEL Geometry courtesy: Ch. Wiebers (DESY) LYSO:Ceor YAP (in Injector), 200 μm e-Beam e-Beam 45° ~ 70 monitors are used along the machine Scintillator CCD CCD downstream Bunch Compressor 1 downstream L3 downstream Bunch Compressor 2 upstream SASE1 Injector Mirror Schneider macrosymmarHM lens Collimation Section TLD upstream L1

  4. Wire Scanner @ 31 nA Scintillator based monitors at XFEL Scintillating material Measurements at Mainz Microtron MAMI LYSO:Ce best spatial resolution σy = 1.44 μm beam size in excellent agreement with independent OTR measurement G. Kubeet al., Proc. IPAC’12, New Orleans (USA), 2012, p.2119 G. Kubeet al., Proc. IPAC’10, Kyoto (Japan), 2010, p.906 G. Kubeet al., Proc. IBIC’15, Melbourne (Australia), 2015, p.330

  5. “Smoke-ring” profile first observation • The shape was observed along all the machine. • The shape leads to higher emittances measured. Excluded options: • COTR contribution • Space charge effects from the gun • CCD saturation Final suspicion is a scintillator effect

  6. HEP Scintillator experience Calorimetry S.A. Payne et al., IEEE Trans. Nucl. Sci. 58 (2011) 3392 It is known from HEP experience: • There is a non-linearity in energy resolution. • An ionization track density is a critical parameter. May we use the experience in the beam profile measurements field? • In case of XFEL electrons have 130 MeV energy already at the very first screens. So we are in so-called Fermi Plateau. • BUT! XFEL has high electron bunch population up to 1010particles/bunch

  7. Scintillating process in details • When a particle goes through a scintillator material it creates plenty of e-h pairs in small area around its track (radius of the area is about 3-5 nm). • Then the e-h pairs should pass several stages to be converted into light we detect later e e h h h A.N. Vasil‘ev, Proc. SCINT’99, Moscow (Russia), 1999, p.43 e e e h h h e e h e h h e e h e h h e e h h e e h h e h

  8. Ionization density at XFEL static homogeneous ionization tubes: 2D representation sufficient lowchargedensity beam high chargedensity beam Instead of having high track ionization density caused by the primary particle high losses, we get the density by having the tracks of the primary particles overlapped.

  9. Quenching model for beam profiles Gaussian beam Birks-type weightfactorforscintillator non-linearity J.B. Birks,Proc. Phys. Soc. A64 (1951) 874 with αis a free adjustable parameter

  10. Model calculation Qb = 1.0 nC σx = 100 μm σy = 50 μm Qb = 0.1 nC σx = 100 μm σy = 50 μm Qb = 0.5 nC σx = 100 μm σy = 50 μm Qb = 0.5 nC σx = 90 μm σy = 50 μm Qb = 0.5 nC σx = 75 μm σy = 50 μm Qb = 0.5 nC σx = 50 μm σy = 50 μm

  11. Measurements at XFEL LYSO/YAG comparison • To compare materials several stations were equipped with two materials - LYSO with additional one. The additional ones were: YAG, YAP, GAGG, LuAG. • To test the materials a quad scan was performed. • E = 14 GeV • Q = 1 nC

  12. Measurements at XFEL LYSO/YAP comparison • E = 14 GeV • Q = 0.45 nC

  13. Measurements at XFEL LYSO/GAGG comparison • E = 14 GeV • Q = 0.45 nC

  14. Conclusion on Quenching Effect • Measured beam sizes are larger than expected. • Quest for suitable scintillator material. • Development of the quenching model and further experimental investigations.

  15. Charging effects at XFEL

  16. Of-axis screens at XFEL Geometry Scheme of the off-axis screen monitors OTRC.55 OTRC.56 OTRC.58 OTRC.59 e--bunch train e--bunch train e--bunch train e--bunch train Allow to measure beam profiles in online mode by kicking a single bunch out fo the whole bunch-train onto the screens. Vacuum chamber

  17. Of-axis screens at XFEL Scintillator holder Off-axis screen holder Normal screen holder Calibration target On-axis scintillator 200 um thick YAP Move in and out Move in and out Off-axis scintillator 200 um thick YAP

  18. Charging effect first observation During emittance measurements with the off-axis screens the SASE level drops in time: • First guess was that the kickers somehow cause the effect. • Downstream BPMs reveal changes in the orbit The screen has been moved out Another screen has been moved in The first screen is back in A screen is in and a bunch is kicked on it Horizontal BPMs reading Vertical BPMs reading

  19. Physics behind the effect • The kickedelectronbunchcausesionization. • Every bunchcanleaveupto 3% ofitscharge in thescintillator(Simulated in GEANT4). • The scintillator material is an insulator → discharging goes slowly. • Every next bunch passing by the scintillator feels the Coulomb force. Nevertheless charging competes with discharging. Thus the behavior of charging in time should be described by the equation:

  20. Measurements scheme To measure the effect we had one of four off-axis screen inserted, kicked one bunch of a bunch train on it continuously and measured a BPM reading downstream. We consider then the charge on he screen is local. Since we have Coulomb force → the deviation downstream depends on the distance between the screen charge and the bunch train. Every position has been measured 300 seconds = 3000 bunchespassed through the scintillator. Bunch charge was 250 pC, electron energy - 130 MeV. To measure the position of the passing by bunches the normal screen was inserted after the measurements and the picture taken.

  21. Measurement #1 • The bunch train consisted of 2 bunches • Number of “on screen” bunch positions was 5 • Distances between on-screen bunches and the central bunch one: • 1 =7.3 mm • 2 = 6.6 mm • 3 = 5.8 mm • 4 = 4.9 mm • 5 = 4.1 mm • Distance between the screen and BPM was 4 m Central e--Bunch 5 1 3 5 5 4 2 4 4 3 Recalculation into charge 2 3 1 2 1

  22. Measurement #1 Fitting formula: This was used for comparison with GEANT simulation. The result of the simulation was that 3 % of a bunch charge should be created in the scintillator after it has passed. Also the losses doesn’t depend on the electron energy in the region of XFEL electrons (around 130 MeV) From the data we have around 6 %

  23. Measurement #2 • The bunch train consisted of 158 bunches • Number of on screen bunch positions was 4 • Distances between on-screen bunches and the central bunch one: • 1 =9.7 mm • 2 = 9.0 mm • 3 = 8.3 mm • 4 = 7.5 mm • Distance between the screen and BPM was 2 m Positive charges 3 1 Central e--bunch Fc 4 2 1 2 3 4 Recalculation into charge

  24. Conclusion on Charging Effect • The beam orbit and the SASE level as a consequence are affected by the charging of the scintillators. • Further systematic studies are planned at XFEL and at our laboratory stand with an electron gun and a scintillator in front of it. • The fast discharging issue still has unknown nature. • Might be useful to cover a scintillator by a conductive layer to discharge it as fast as possible.

  25. Thankyou

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