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11/18/2008 Global Design Effort 1 Summary for Gamma-Gamma Mayda M. Velasco Northwestern University November 20, 2008 LCWS08 -- UIC, Chicago
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11/18/2008 2 Linear Collider Workshop – November 16-20, 2008 As pointed out in the past: Photon Linear Collider (PLC) is a simple & elegant idea Laser Compton interaction produces beam of high energy photons –E <= 0.8 E beam Peak has high circular polarization –Linear polarization is also possible –CP studies The effective cross section for processes like gg-->h is high, compensating for the lower luminosity Lgg~0.2Le+e- Question: Is it cost effective to make low energy PLC, ff LHC find a “light” Higgs
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11/18/2008 3 Linear Collider Workshop – November 16-20, 2008 Basic Physics Case for a Low Energy & High Energy PLC already stablish Low Energy High Energy
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11/18/2008 4 Linear Collider Workshop – November 16-20, 2008 PLC: Issues & Facts discussed at joint session with XX group Polarization needed to obtain high luminosity @ E_gg ~0.8 E+_ee –Damping rings needed due to high emittances of beam produced with DC photo-guns –Hope... Future RF polarized sources Interactions of Laser with e-beam disruptive –Large crossing angle needed Detector the same as for e+e- for theta>7o At small angles masking is needed to protect the detector Beam dump: photon beam cannot be deflected therefore the energy density at the dump is large –Request: proper simulation & design needed
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11/18/2008 5 Linear Collider Workshop – November 16-20, 2008 The photon collider needs a laser pulse for every electron bunch Average power ~15kW / beam Formatted in time to match the electron time structure 120 pulses separated by 2.8 ns Cold SRF Warm X-band, S-band, CLIC
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11/18/2008 6 Linear Collider Workshop – November 16-20, 2008 e-e- ??? –significant price cut if positron sources not needed? –how different the IP issues will become?
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11/18/2008 7 Linear Collider Workshop – November 16-20, 2008 The MERCURY laser is an attempt to create high average power with good efficiency Goal: 100 J 10 Hz 10% Efficiency 2-10 ns < 5X Diffraction limit > 10 8 shots Output Diode arrays 8 diode arrays 6624 diodes total 730 kW peak power Front-end 300 mJ Gas-cooled amplifier heads Helium gas flow at 0.1 Mach Cavity Laser: 764 W average power 119 kW peak power
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11/18/2008 8 Linear Collider Workshop – November 16-20, 2008 beam splitter optical delay line polarizer wave plate 120 hz of 100 J macro-pulses from 12 MERCURY lasers 100 J laser macro-pulse converted to train of 1 J subpulses Straw-man laser for NLC presented at Snowmass 2001 IR optics Single pulse to pulse train “hall of mirrors” MERCURY laser plant
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11/18/2008 9 Linear Collider Workshop – November 16-20, 2008 Diode arrays are mature and industrialized Offline tile tests: 1.5 x 10 8 shots Mercury diode arrays: 5 x 10 6 shots
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11/18/2008 10 Linear Collider Workshop – November 16-20, 2008 Helium flow cooling manages the heat load in the crystals Corrector plates will remove the residual wavefront distortion once the final configuration is in place
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11/18/2008 11 Linear Collider Workshop – November 16-20, 2008 Methodologies for growing the amplifier crystals are in place The crystals can be economically grown and processed
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11/18/2008 12 Linear Collider Workshop – November 16-20, 2008 MERCURY technology has been under development since 2001 Operation at 10 Hz with 55 Joule pulses for 8 hours 10 ns width pulses –Has the bandwidth to support ps pulse but not demonstrated 5x diffraction limit wavefront quality –Final wavefront corrections not done Large improvements in diode cost and crystal growth and processing
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11/18/2008 13 Linear Collider Workshop – November 16-20, 2008 Most laser power is unused - A recirculating cavity can reduce required laser power 5 Hz operation 1000+2820 bunches / train 40mJ / pulse 764 W average power 119 kW peak diode power 2004 Cold SRF technology chosen for ILC Inter-bunch spacing allows possibility of recirculation Stacking cavity design from MBI / DESY- Zeuthen G. Klemz et al. Laser requirements:
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11/18/2008 14 Linear Collider Workshop – November 16-20, 2008 A layout for integrating the laser cavity and detector and detector was proposed MBI/DESY laser stacking cavity design: - 369 ns path length - factor 300 reduction in total laser power D etector must be modified to accommodate the laser and to remove the disrupted electron beam
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11/18/2008 15 Linear Collider Workshop – November 16-20, 2008 Since then smaller recirculating cavities have been developed for Compton light sources Resonant cavities are being developed for: –Polarized positron source –Laser wire –Beam diagnostics –Medical and industrial applications –Photon collider e- beam tube beam Interaction point e- beam LAL - Orsay KEK - Hiroshima
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11/18/2008 16 Linear Collider Workshop – November 16-20, 2008 It is time to develop a conceptual design for a photon collider laser Average power of ~500W –Been done before –But not with ps pulse Good wavefront quality Time formatting In 2009 we will create a conceptual design for the laser system –Identify any technology limitations –Understand the R&D path to demonstrating a workable system
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