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Compton Linac for Polarized Positrons V. Yakimenko, I. Pogorelsky, M. Polyanskiy, M. Fedurin BNL CERN, October 15, 2009.

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Presentation on theme: "Compton Linac for Polarized Positrons V. Yakimenko, I. Pogorelsky, M. Polyanskiy, M. Fedurin BNL CERN, October 15, 2009."— Presentation transcript:

1 Compton Linac for Polarized Positrons V. Yakimenko, I. Pogorelsky, M. Polyanskiy, M. Fedurin BNL CERN, October 15, 2009

2 Polarized positron source: the concept CO 2 amplifier Interaction point Metallic target - A picosecond CO 2 laser pulse circulates in a ring cavity - At each pass through the cavity the laser pulse interacts with a counter-propagating electron pulse generating γ- quanta via Compton scattering - Optical losses are compensated by intracavity amplifier - The λ-proportional number of photons per Joule of laser energy allows for higher γ- yield (compared to solid state lasers) Pulse duration:5 ps Pulse energy:1J Repetition: 3-12 ns Pulses/bunch:100

3 Polarized positron source Conventional Non-Polarized Positrons: 3% over 1  s First tests of the laser cavity Polarized γ-ray beam is generated in the Compton back scattering inside optical cavity of CO 2 laser beam and 6 GeV e- beam produced by linac. 6GeV e - beam 60MeV  beam 30MeV e + beam  to e + conv. target ~2 m

4 Linac Compton Source (LCS): Numbers Positron beam requirement ILCCLIC 2 10 10 /3 nc4 10 9/ 0.6 nc 2656@5Hz312@50Hz e- beam energy4 / 6 GeV e- bunch charge15 / 10 nC6 / 4 nC RMS bunch length (laser & e - beams) 3ps Number of laser IPS105 Total N  /Ne - yield (in all IPs)105 Ne + /N  capture2 / 3 % Ne + /Ne - yield20 / 30 %10 / 15% Total e + yield3 nC0.6 nC # of stackingNo stacking Normalized e+ emittance6 / 4 mm rad3 / 2 mm rad

5 Computer simulations: Model Pumping (slow time-scale) Vibrational relaxation (slow time-scale) Amplification & Rotational relaxation (fast time-scale) Beam Propagation (diffraction, optics, losses) Spectra (amplification band) Boltzmann equations (discharge energy distribution) Discharge dynamics Using data from HITRAN2008

6 Simulation results Natural CO 2 O 16 :O 18 = 50:50 Pulse energy dynamics

7 Simulation results Natural CO 2 O 16 :O 18 = 50:50 Pulse energy dynamics Gain spectra

8 Simulation results Natural CO 2 O 16 :O 18 = 50:50 Pulse energy dynamics Pulse spectra (initial and after reaching 1 J)

9 Simulation results Natural CO 2 O 16 :O 18 = 50:50 Pulse energy dynamics Pulse spectra (initial and after reaching 1 J) Temporal pulse profile (initial and after reaching 1 J)

10 Pulse diagnostics Total bandwidth Individual pulse sub-ps resolution Individual lines Train resolution improvement needed “Streak camera” :) Single-shot :( Low resolution (~10 ps ) :) Train measurements 10μm Laser diode 0.9 μm 0.8 μm Mixing crystal Filter CO 2 Streak camera time 25 ps Measured Simulated “Interferometer” “Spectrometer” Pyrocamera Δt = 05 ps10 ps Pyrocamera Diffractive grating wavenumber 1.3 cm -1 Fourier transform Measured Simulated :) Single-shot :) Simple = reliable :) Indiv. pulse measurements... Train measurements (?) :( Indirect method Fourier transform :( Multiple-shot :) Indiv. pulse measurements :) Train measurements :( Complicated data analysis 25 ps50 ps75 ps Individual pulse Train

11 Laser system

12 Possible configuration with 5 IPs and 1 laser amplifier ~15 cm ~1m

13 Wall plug power consideration ILC: – 3 10 14 positrons/second; – 2%  - > e + efficiency for 60 MeV  => 150 kW  beam Wall plug to  for warm linac/CO2 is expected ~5-10%

14 Cross section for Pair production

15 Positron generation efficiency

16 Angular spread of positron beam

17 Positron beam size at the target exit

18 Normalized emittance at the target exit

19 Positron generation efficiency normalized by emittance

20 Positron generation efficiency normalized by emittance and gamma beam power

21 Positron generation efficiency normalized by transverse phase space

22 Positron generation efficiency normalized by transverse phase space and gamma beam power

23 Conclusion Polarized positron beam requirement for CLIC can be satisfied with Compton CO2/LINAC based gamma source Higher energy gamma beam is preferential for the thermal load on the target Shorter target is preferential when low emittance after target is needed (CLIC, LeHC …) Total power consumption should be part of optimization for high positron demands (LeHC) Amplification in Isotope mixture will be tested shortly at ATF Seed pulse generation using solid state laser will be tested at ATF in ~year There is no funding/activity for regenerative cavity test

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