A Tunable (1100-nm to 1500-nm) 50-mJ Laser Enables a Pump-Depleting Plasma-Wave Amplifier Focused intensity (W/cm 2 ) 10 30 10 25 10 20 10 15 10 10 Nonlinear quantum electrodynamics (QED) Ultrarelativistic optics Relativistic optics Plasma physics Mode locking Q switching Chirped-pulse amplification (CPA) Atomic physics RPA A. Davies University of Rochester Laboratory for Laser Energetics 1960 1970 1980 1990 Year 2000 2010 57th Annual Meeting of the American Physical Society Division of Plasma Physics Savannah, GA 16 20 November 2015 1
Summary A high-energy, tunable Raman amplification experiment is designed to quickly enter the pump-depletion stage Raman amplification has the potential to surpass current laser power limitations Two independent laser systems will provide the pump (50 J) and seed (50 mj) The pump-depletion stage coincides with the presence of large-amplitude electron plasma waves that will be detected with Thomson scattering E24633 2
Collaborators S. Bucht, J. Katz, D. Haberberger, J. Bromage, J. D. Zuegel, and D. H. Froula University of Rochester Laboratory for Laser Energetics P. A. Norreys Central Laser Facility, Appleton Laboratory R. Bingham University of Strathclyde J. Sadler University of Oxford, Clarendon Laboratory R. Trines Rutherford Appleton Laboratory L. O. Silva Instituto Superior Tecnico 3
The next generation of high-intensity lasers requires a paradigm shift in technology Present-day petawatt-class lasers are limited by the grating damage threshold broadband gratings: fluence limit ~0.1 J/cm 2 Plasma amplifiers have the potential to reach higher peak powers by avoiding the damagethreshold obstacle plasma fluence limit: ~1000 J/cm 2 (assuming a 10-fs pulse) Focused intensity (W/cm 2 ) 10 30 10 25 10 20 10 15 10 10 Nonlinear quantum electrodynamics (QED) Ultrarelativistic optics Relativistic optics Plasma physics Mode locking Q switching Chirped-pulse amplification (CPA) Atomic physics RPA 1960 1970 1980 1990 2000 2010 E24634 RPA: Raman plasma amplifier 4
A plasma amplifier works by transferring energy from a long (tens of ps) energetic pump pulse into a short (tens of fs) counter-propagating seed pulse Raman Instability p m Pu d e Se d ve a aw fie i l p m A ed se p m u p ted m s a l P Time dn e v v d ae # E pump seedk v E seed ple De kv pump = kv seed + kv p v E pump # dn e ~ pump = ~ seed + ~ p This localized backscattering can effectively compress the high-energy pump into a high-intensity short pulse. E24635 5
Raman amplification at the Laboratory of Laser Energetics will utilize existing laser systems to provide the pump and seed Pump Seed Multi-Terawatt (MTW) Laser System m = 1053 nm Energy = 50 J Dt = 1 to 100 ps Spectra (normalized) 1.0 0.8 0.6 0.4 0.2 0.0 Example seed spectra 1100 1150 Optical parametric amplifier line (OPAL) m = 1100 to 1500 nm Energy = 50 mj Dt = 50 fs Seed wavelength (nm) 1300 1250 1200 1150 1100 1050 0 ~ seed = ~ pump ~ p 1 2 3 4 Wavelength (nm) Plasma density (cm 3 ) ( 10 19 ) E23502a 6
The seed and pump will cross out of focus at a small angle in a 4-mm-long hydrogen gas cell Seed in f/26 focus, f = 120 cm 4 angle between beams Pump in Gas cell Unique conditions long homogeneous plasma density Pump out 4-mm hydrogen gas cell Seed out Noncollinear interaction isolate scattering sources Pump Energy = 50 J Dt = 25 ps Radius = ~300 nm Intensity = 10 15 W/cm 2 m pump = 1053 W/cm 2 Seed Energy = 50 mj Dt = 50 fs Radius = ~300 nm Intensity = 10 14 W/cm 2 m seed = 1100 to 1200 nm High energy practical energies for PW laser system High-intensity seed quickly enter pumpdepletion stage E23504a 7
To create a long homogenous plasma target, a gas cell target has been constructed and characterized using interferometry Density in 4-mm gas cell 7 Atomic density (cm 3 ) ( 10 18 ) 6 5 4 3 2 1 0 2.0 1.5 1.0 0.5 0.0 rms*. 4% 0.5 1.0 1.5 2.0 x (mm) E24636 *rms: root mean square 8
Particle-in-cell simulations predict 40% pump depletion and a nonlinear electron plasma wave (EPW) log 10 [intensity (W/cm 2 )] 16 15 14 13 340 Depleted pump Pump + seed intensity 360 380 Seed Distance (nm) Input pump Electron density (cm 3 ) ( 10 19 ) 2.0 1.5 1.0 0.5 0.0 400 420 2440 Driven EPW 2460 2480 Distance (nm) 2500 2520 E24760 9
Thomson scattering will spatially and temporally resolve the driven EPW s frequency and amplitude kv = kv + kv scatter probe p k scatter k seed k pump EPW Gas cell k p k scatter k probe k probe 2i h = sin rl D n 2n m m cos i probe p e c scatter ~ scatter= ~ probe + ~ p E24638 10
Summary/Conclusions A high-energy, tunable Raman amplification experiment is designed to quickly enter the pump-depletion stage Raman amplification has the potential to surpass current laser power limitations Two independent laser systems will provide the pump (50 J) and seed (50 mj) The pump-depletion stage coincides with the presence of large-amplitude electron plasma waves that will be detected with Thomson scattering E24633 11