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Doe FACET Review February 19, 2008 A Plasma Wakefield Accelerator-Based Linear Collider Vision for Plasma Wakefield R&D at FACET and Beyond e-e+Colliding Plasma Wakes Simulation, F. Tsung Beyond 10 GeV: Results, Plans and Critical Issues T. Katsouleas University of Southern California
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Outline Brief History and Context Introduction to plasma wakefield accelerators Path to a high energy collider Critical issues, milestones and timeframe What can and cannot be addressed with FACET
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Plasma Accelerators -- Brief History 1979 Tajima & Dawson Paper 1983 Tigner Panel rec’d investment in adv. acc. 1985 Malibu, GV/m unloaded beat wave fields, world-wide effort begins 1989 1st e- at UCLA 1994 ‘Jet age’ begins (100 MeV in laser-driven gas jet at RAL) 2004 ‘Dawn of Compact Accelerators’ (monoenergetic beams at LBL, LOA, RAL) 2007 Energy Doubling at SLAC RAL LBL Osaka UCLA E164X/E-167 ILC Current Energy Frontier ANL LBL
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Research program has put Beam Physics at the Forefront of Science Acceleration, Radiation Sources, Refraction, Medical Applications
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Charge
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Particle Accelerators Requirements for High Energy Physics High Energy High Luminosity (event rate) L=fN 2 /4 x y High Beam Quality Energy spread ~.1 - 10% Low emittance: n y y << 1 mm-mrad Low Cost (one-tenth of $10B/TeV) Gradients > 100 MeV/m Efficiency > few %
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Simple Wave Amplitude Estimate Gauss’ Law E 1-D plasma density wave V ph =c
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Linear Plasma Wakefield Theory Large wake for a laser amplitude a beam density n b ~ n o Requirements on I, require a FACET-class facility Ultra-high gradient regime and long propagation issues not possible to access with a 50 MeV beam facility Q/ z = 1nCoul/30 (I~10 kA) For z of order c p -1 ~ 30 (10 17 /n o ) 1/2 and spot size =c/ p ~ 15 (10 17 /n o ) 1/2 :
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Nonlinear Wakefield Accelerators (Blowout Regime) Plasma ion channel exerts restoring force => space charge oscillations Linear focusing force on beams (F/r=2 ne 2 /m) Synchrotron radiation Scattering Rosenzweig et al. 1990
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E+ E- Beam propagation Head erosion (L= Hosing Transformer Ratio: driver load Limits to Energy Gain
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PIC Simulations of beam loading Blowout regime flattens wake, reduces energy spread Unloaded wake EzEz Beam load U C L A Loaded wake N load ~30% N max 1% energy spread
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Emittance Preservation Plasma focusing causes beam to rotate in phase space Emittance n = phase space area: 1/4 betatron period (tails from nonlinear F p ) Several betatron periods (effective area increased) x pxpx Matching: Plasma focusing (~2 n o e 2 ) = Thermal pressure (grad p / 3 ) No spot size oscillations (phase space rotations) No emittance growth FpFp F th
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Positron Acceleration -- two possibilities blowout or suck-in wakes Ref. S. Lee et al., Phys. Rev. E (2000); M. Zhou, PhD Thesis (2008) Non-uniform focusing force (r,z) Smaller accelerating force Much smaller acceptance phase for acceleration and focusing e-e- e+e+ e+ load
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On ultra-fast timescales, relativistic plasmas can be robust, stable and disposable accelerating structures TESLA structure Plasma 2a ~ 30cm ~ 100 m Accelerator Comparison No aperture, BBU
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Path to a TeV Collider from present state-of-the-art* Starting point: 42 --> 85 GeV in 1m –Few % of particles Beam load –25-50 GeV in ~ 1m –2nd bunch with 33% of particles –Small energy spread Replicate for positrons Marry to high efficiency driver Stage 20 times * I. Blumenfeld et al., Nature 445, 741 (2007)
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CLIC-like PWFA LC Schematic Drive Beam Accelerator 12 usec trains of e- bunches accelerated to ~25 GeV Bunch population ~3 x 10 10, 2 nsec spacing 100 trains / second Main Beam e+ Source:500 nsec trains of e- bunches Bunch population ~1 x 10 10, 2 nsec spacing 100 trains / second DR PWFA Cells: 25 GeV in ~ 1 m, 20 per side ~100 m spacing DR Main Beam e- Source: 500 nsec trains of e- bunches Bunch population ~1 x 10 10, 2 nsec spacing 100 trains / second Beam Delivery System, IR, and Main Beam Extraction / Dump ~2 km ~60 MW drive beam power per side ~20 MW main beam power per side ~120 MW AC power per side ~ 4 km 1TeV CM
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Drive Beam Source DC or RF gun Train format: With 3 x 10 10 /bunch @ 100Hz: ~2.3 mA average current, ~2 A beam current, similar to beam successfully accelerated in CTF3 Compress bunches to ~30 RMS length SPPS achieved much smaller RMS lengths Accelerate to 25 GeV Fully-loaded NC RF structures, similar to CLIC / CTF 3 Inject into “Drive Beam Superhighway” with pulsed extraction for each PWFA cell Both e+ and e- main beams use e- drive beam See slide notes for additional background 100ns kicker gap mini-train 1 mini-train 20 500ns: 250bunches 2ns spacing 12 s train
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Drive Beam Superhighway Based on CLIC drive beam scheme –Drive beam propagates opposite direction wrt main beam –Drive mini-train spacing = 2 * PWFA cell spacing i.e, ~600 nsec
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Drive Beam Distribution Format options –Mini-trains < 600 nsec NC RF for drive beam Duty cycle very low –Individual bunches > 12 μsec SC RF for drive beam Duty cycle ~100 %
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Main Beam Source and Plasma Sections Electron side: DC gun + DR Compress to 10 (achieved in SPPS) 20, +25GeV plasma sections, each 1E17 density, <1.2 meters long Gaussian beams assumed -shaped beam profiles => larger transformer ratio, higher efficiency Final main beam energy spread <5% Positron side: conventional target + DR Positron acceleration in electron beam driven wakes (regular plasma or hollow channel) Will have tighter tolerances than electron side
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Matching / Combining / Separating Main and Drive Beams Must preserve bunch lengths Preserve emittance of main beam ~100 μm spacing of main and drive bunches –Time too short for a kicker – need magnetostatic combiner / separator –Need main – drive bunch timing at μm level Different challenges at different energies –High main beam energy: emittance growth from SR –Low main beam energy: separation tricky because of ~equal beam energies Need ~100 m between PWFA cells “First attempt” optics of 500 GeV / beam separator. First bend and first quad separate drive and main beam in x (they have different energies); combiner is same idea in reverse. This optics needs some tuning and ~2 sextupoles. System is isochronous to the level of ~1 μm R 56. Assuming that another ~50 m needed for combiner, each PWFA cell needs ~100 m of optics around it.
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TeV Beam Parameter Summary IP Parameters* e+ e- h.e. bunch gamepsX [m]2.0E-06 h.e. bunch gamepsY [m]5.0E-08 beta-x [m]5.0E-02 beta-y [m]2.0E-04 sigx [m]3.2E-07 sigy [m]3.2E-09 sigz [m]1.0E-05 Dy5.6E-01 Uave2.81 delta_B0.14 P_Beamstrahlung [W]2.9E+06 ngamma0.79 Hd1.2 Lum. [cm-2 s-1]2.4E+34 Int. Lum. [fb-1 per 2E7s]474 Coherent pairs/bc2.2E+07 E CM at IP [GeV]1000 N, drive bunch2.9E+10 N, high energy bunch1.0E+10 n h.e. bunch/sec [Hz]25000 Main beam train length [nsec]500 Main beam bunch spacing [nsec]2 Main beam bunches / train250 Repetition rate, Hz100 PWFA voltage per cell [GV]25 PWFA Efficiency [%]35 # of PWFA cells20 n drive bunch/sec [Hz]500000 Drive bunch energy [GeV]25 Power in h.e. beam [W]2.0E+07 Power in drive beam [W]5.7E+07 Avg current in h.e. beam [uA]40.05 Avg current in drive beam [mA]2.29 Modulator-Drive Beam Efficiency [%]54 Site power overhead [MW]71 Total site power [MW]283 Wall Plug Efficiency 14% *If DR emittance is preserved
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Other Paths to a Plasma-based Collider Hi R options --> 100 GeV to TeV c.m. in single stage –Ramped drive bunches or bunch trains –Plasma question: hose stability –RF Driver questions: pulse shaping techniques, drive charge is 5x larger SRF Driven Stages –5 stage example of Yakimenko and Ischebeck –Plasma question: extrapolate to 2m long 100 GeV –SRF questions: 3x5 +1 times the power/m and loading of ILC, wakes and BBU Laser drivers –Extrapolate 1 GeV experiments to 25 GeV Scale up laser power x25, pulse length x5, density x0.04, plasma length x125 20 Stages –Plasma questions: channel guiding over 1m; injected e-; e+ behind bubble –Laser questions: Avg. laser power (20MW/ ) needs to increase by 10 2 -10 4
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Critical Issues System Req.IssueTech Drivers N Load 2nd bunchChicane+chirp photocathode Load 2nd bunchBunch shape Phase control nn Matching hosing Scattering Ion motion Plasma sources Plasma channels plasma matching sections Combiner/separators e+ Gradients Nonlinear focusing Accel on e- wake Plasma channels e+ sources phase control E Beam propagation Synchrotron losses Staging or shaping Simulation modeling to guide designs Laser jitter stabilization f Power coupling RF stability w/ hi load, short bunch (CSR) Gas removal & replenish Klystron power CLIC DoD Gas laser program L Final Focus-Plasma lens’ Pointing stability Plasma sources Ultra-fast feedback Red=FACET only Blue=FACET Green=Facet partial
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R&D Roadmap for a Plasma-based Collider
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Summary Recent success is very promising No known show stoppers to extending plasma accelerators to the energy frontier Many questions remain to be addressed for realizing a collider FACET-class facility is needed to address them –Lower energy beam facilities cannot access critical issues in the regime of interest –FACET can address most issues of one stage of a 5-20 stage e-e+ TeV collider
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Backup and Extra
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Future upgrade or alternative paths PWFA can be an upgrade path of e-e- or options The following flow corresponds to the afterburner path
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Beam delivery NLC style FF with local chromatic correction can be a starting point ~TeV CM required just ~300m Energy acceptance (full) was about 2% – within a factor of two from what is needed for PWFA-LC (further tweaking, L* optimization, etc) Beam delivery length likely be dominated by collimation system (could be +1.0-1.5km/side) – methods like crystal collimation and nonlinear collimations to be looked at again An early (2000) design of NLC FF L* =2m y *=0.1mm
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1 TeV Plasma Wakefield Accelerator 5, 100 GeV drive pulses, SC linac Trailing Beam ~10 µs+ Trailing Beam Ref.: V. Yakimenko and R. Ischebeck, AIP conference proceedings 877, p. 158 (2006). ~1 ns PWFA Modules P
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