1. Laser-Heated Capillary Discharge Plasma Waveguides for Electron Acceleration to 8 GeV
- Author
-
C. G. R. Geddes, G. Bagdasarov, Carlo Benedetti, Carl Schroeder, Lieselotte Obst-Huebl, Pavel V. Sasorov, Kohji Nakamura, Stepan Bulanov, Eric Esarey, V. A. Gasilov, Cs. Toth, Wim Leemans, Jianhui Bin, N. A. Bobrova, R. G. W. van den Berg, J. van Tilborg, G. Korn, J. Daniels, Sven Steinke, C. V. Pieronek, Anthony Gonsalves, and Applied Physics and Science Education
- Subjects
Classical Physics ,Fluids & Plasmas ,Electron ,01 natural sciences ,Atomic ,010305 fluids & plasmas ,law.invention ,Particle and Plasma Physics ,Affordable and Clean Energy ,law ,Physics::Plasma Physics ,Ionization ,0103 physical sciences ,ddc:530 ,Nuclear ,010306 general physics ,Physics ,Bremsstrahlung ,Pulse duration ,Molecular ,Plasma ,Condensed Matter Physics ,Laser ,Bunches ,Plasma channel ,Atomic physics ,Astronomical and Space Sciences - Abstract
Physics of plasmas 27(5), 053102 (2020). doi:10.1063/5.0002769, A plasma channel created by the combination of a capillary discharge and inverse Bremsstrahlung laser heating enabled the generation of electron bunches with energy up to 7.8 GeV in a laser-driven plasma accelerator. The capillary discharge created an initial plasma channel and was used to tune the plasma temperature, which optimized laser heating. Although optimized colder initial plasma temperatures reduced the ionization degree, subsequent ionization from the heater pulse created a fully ionized plasma on-axis. The heater pulse duration was chosen to be longer than the hydrodynamic timescale of ���1 ns, such that later temporal slices were more efficiently guided by the channel created by the front of the pulse. Simulations are presented which show that this thermal self-guiding of the heater pulse enabled channel formation over 20 cm. The post-heated channel had lower on-axis density and increased focusing strength compared to relying on the discharge alone, which allowed for guiding of relativistically intense laser pulses with a peak power of 0.85 PW and wakefield acceleration over 15 diffraction lengths. Electrons were injected into the wake in multiple buckets and times, leading to several electron bunches with different peak energies. To create single electron bunches with low energy spread, experiments using localized ionization injection inside a capillary discharge waveguide were performed. A single injected bunch with energy 1.6 GeV, charge 38 pC, divergence 1 mrad, and relative energy spread below 2% full-width half-maximum was produced in a 3.3 cm-long capillary discharge waveguide. This development shows promise for mitigation of energy spread and future high efficiency staged acceleration experiments., Published by American Institute of Physics, [S.l.]
- Published
- 2020
- Full Text
- View/download PDF