Progress with Laser Plasma Acceleration and Prospects of LPA HEP Colliders

1. Progress with Laser Plasma Acceleration  and Prospects of LPA HEP Colliders Wim Leemans LOASIS Program and BELLA Team APS-DPF Meeting August 12, 2011 Lawrence Berkeley National Laboratory UC Berkeley http://loasis.lbl.gov/

2. X-rays SLAC 50 GeV DNA LHC 2 GeV 7 TeV Accelerators: drivers for science

3. m-scale Laser plasma acceleration enables development of “compact” accelerators 10 – 40 MV/m 100 micron-scale 10 – 100 GV/m ΔW=Ez x L Plasmas sustain extreme fields => compact accelerators Can this technology be developed for energy frontier machines, light sources, medical or homeland security applications? 3

4. Wall plug efficiency, technology choice Ez = O(10 GV/m) Beam power, beam quality Wish list for an e+ - e- TeV collider ... Energy = O(1 TeV, c.m.) Length = O(soccer field) Luminosity > 1034 cm-2 s-1 Cost = Affordable

6. Key technical challenges for Laser Plasma Accelerators PW-class BELLA laser laser 10-100 TW Multi-GeV beams Staging, optimized structures High quality beams Modeling Diagnostics/Radiation sources Lasers: high average power

7. 2006 result: 40 TW laser, cm-scale plasma Channel guided laser plasma accelerators have produced up to GeV beams from cm-scale structures 1.1 GeV <2.9% <1 mrad 10-30 pC W.P. Leemans et. al, Nature Physics2, p696 (2006) K. Nakamura et al., Phys. Plasmas 14, 056708 (2007) 2004 result: 10 TW laser, mm-scale plasma ~100 MeV C. G. R. Geddes,et al, Nature,431, p538 (2004) S. Mangles et al., Nature 431, p535 (2004) J. Faure et al., Nature 431, p541 (2004) 7

8. A GeV module…

9. Injected Out of Phase Injected Electrons Self Injection Electrons surfing on a wave: controlled injection • Trapping requires: • Tsunami • Boost electrons or slow down wave

10. Longitudinal density tailoring allows trapping control S.V. Bulanov et al., PRL 78, (1997); Geddes et al., PRL V 100, 215004 (2008); A.J. Gonsalves et al., submitted (2010)

11. Practical implementation of combined injector and acceleration stage Supersonic gas jet embedded into capillary Laser 0.1-1 GeV Acceleration section Injector 3 cm 11

12. Tunable electron beams produced with jet+capillary module using laser focus control Energy variation for fixed focus <1.9 % rms Divergence change < 0.57 mrad rms Energy variation < 2 % rms Charge variation < 6 % rms Divergence change < 0.57 mrad rms Jet density 7 × 1018 cm−3 Capillary density 1.8 × 1018 cm−3, a0~1.5 A.J. Gonsalves et al., accepted Nature Physics

13. Electron beam can be steered using plasma channel alignment capillary axis θcap laser axis High -6 Center θcap (mrad) 0 Low 5 4

14. Emittance control via laser mode • Beam detection and transport Laser Elong Etrans e- beam laser Coherent Optical Transition Radiation Techniques for improving beam quality, reproducibility, control being improved • Tunable energy, low ΔE/E

15. First XUV light observed from LPA beam through THUNDER undulator Magnetic spectrometer XUV spectrometer Undulator Beam diagnostics e-beam from LPA imaged with quadrupole magnets ~ 7.5 meter Electron beam spectra XUV light ~40 nm

16. Key technical challenges for Laser Plasma Accelerators PW-class laser laser 10-100 TW Multi-GeV beams Staging, optimized structures High quality beams Modeling Diagnostics/Radiation sources Lasers: high average power

17. Renewable mirrors Staging: solving the issue of depletion of laser energy laser laser Regular mirror Staging or tape Plasma mirror Injector+capillary Structure-to-structure LPA 1 LPA 2 Damage threshold sets mirror size Mirror Size (meter) • Experiments underway at LBNL • Key technology for collider Power (TW)

18. Key technical challenges for Laser Plasma Accelerators PW-class laser laser 10-100 TW Multi-GeV beams Staging, optimized structures High quality beams Modeling Diagnostics/Radiation sources Lasers: high average power

19. C.B. Schroeder et al., PRSTAB 2010

20. BELLA Facility: state-of-the-art PW-laser for laser accelerator science High power diagnostic Plasma source Compressor 10˚ Off-axis parabola BELLA Laser Control Room Gowning Room

21. BELLA Laser System Status – 2011 Summer Amp3 (61 J) components installed – July 2011 Amp2 (22 J) accepted – June 2011 12 Gaia-s operational in laser room – July 2011 Compressor chamber manufactured – July 2011

22. Laser ~10 GeV Petawatt, 1 Hz BELLA laser enables R&D on 10 GeV collider module e- beam 1000 TW 40 fs < 100 cm Lorentz boosted frame simulation Full 1 m BELLA stage -- major advance Courtesy of J.-L. Vay 2013 Experiments • Accelerator science studies • - 10 GeV Module for collider, (10 GeV, beam optimization, efficiency etc…) • - Positron production; plasma wakefield acceleration, etc... • Applications: • Hyperspectral radiation: coherent THz; X-ray FEL driver • Detector testing; Non-linear QED

23. Key technical challenges for Laser Plasma Accelerators PW-class laser laser 10-100 TW Multi-GeV beams Staging, optimized structures High quality beams Modeling Diagnostics/Radiation sources Lasers: high average power

24. Security Apps (5-10 yrs) Medical (10 yrs) Lightsource (10 yrs) Collider (>20 yrs) Laser development Laser plasma accelerator (today)

25. 1 TeV case: 420 kW/laser, 13 kHz (32 J/pulse) with 30% wall plug efficiency and we need 100 of them 25

26. Laser technology: key component for sustained progress • How to reach laser average power levels needed for science apps? • Develop roadmap for science and technology to develop next generation lasers: • Important for accelerators (see Accelerators for America’s Future document) • Unique differences between lasers for defense and for science • Will require major research investment at National Labs, Universities and Industry with potential for international collaborations • ICFA-ICUIL Joint Taskforce for roadmap development

27. Novel lasers and materials are being developed • Amplifiers • Rods, slabs, discs and fibers O(10 kW) fibers (CW power) reality now! • Materials for amplifiers, mirrors and compressor gratings • Ceramics and diamond • Nano-fabricated structures • Diodes and small quantum defect materials

28. Major investments - Example: European Extreme Light Infrastructure - Four pillars (three funded at 790Meuro): 1. attosecond and XUV science: Hungary 2. High-brightness x-ray and particle sources: Czech Republic 3. Photo-nuclear science, transmutation,...: Romania 4. Ultra-high intensity science (non-lin QED): Russia ??? 28

30. Conclusion • Laser plasma accelerator science is vibrant • GeV beam demonstrated with %-level energy spread • BELLA facility aims at 10 GeV in 1 meter • FEL proof-of-principle experiments towards Light Source Facility • Gamma-ray sources, medical and other applications • Collider is still far off but basic concepts are being developed: • Operation in quasi-linear regime for e- and e+ acceleration • Transverse control of plasma profile for guiding laser beam • Injection control and efficiency optimization: • Longitudinal control of plasma profile • Laser mode control allows emittance control • Low emittance observed -- FEL experiment will be litmus test • Laser technology must undergo revolution towards high average power 30

31. Team, collaborators and funding Primary collaborators Staff S. Bulanov (T, UCB) E. Esarey (T) C. Geddes (S+E) A. Gonsalves (E) W. Leemans (E) N. Matlis (E) C. Schroeder (T) C. Toth (E) J. van Tilborg (E) Eng/Techs R. Duarte Z. Eisentraut A. Magana S. Fournier D. Munson K. Sihler D. Syversrud N. Ybarrolaza Postdocs K. Nakamura (E) M. Chen (S) C. Benedetti (S+T) T. Sokollik (E) Students M. Bakeman (PhD) -- graduated 2011 C. Lin (PhD) -- graduated 2011 R. Mittal (PhD) G. Plateau (PhD) -- graduating 2011 S. Shiraishi (PhD) D. Mittelberger (PhD) C. Koschitzki (PhD) B. Shaw (PhD) L. Yu (PhD) • LBNL: M. Battaglia, W. Byrne, J. Byrd, W. Fawley, K. Robinson, D. Rodgers, R. Donahue, Al Smith, R. Ryne. • TechX-Corp: J. Cary, D. Bruhwiler, et al. SciDAC team • Oxford Univ.: S. Hooker et al. • DESY/Hamburg: F. Gruener et al. • GSI: T. Stoehlker, D. Thorn • Trieste: F. Parmigiani BELLA Team members S. Zimmermann J. Coyne D. Lockhart G. Sanen S. Walker-Lam K. Barat