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Differential pumping for kHz operation of a Laser Wakefield accelerator based on a continuously flowing Hydrogen gas jet

Published 25 Oct 2024 in physics.plasm-ph, physics.acc-ph, and physics.optics | (2410.21309v3)

Abstract: Laser-Wakefield Accelerators (LWFA) running at kHz repetition rates hold great potential for applications. They typically operate with low-energy, highly compressed laser pulses focused in high-pressure gas targets. Experiments have shown that the best-quality electron beams are achieved using Hydrogen gas targets. However, continuous operation with Hydrogen requires a dedicated pumping system. In this work, we present a method for designing a differential pumping system, which we successfully implemented in our experiments. This enabled the first demonstration of continuous operation of a kHz LWFA using a high-pressure Hydrogen gas jet. The system effectively maintained a pressure below 3e-4 mbar, even with a free-flowing gas jet operating at 140 bar backing pressure. Numerical fluid dynamics and optical simulations were used to guide and validate the system's design.

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References (14)
  1. T. Tajima and J. M. Dawson, Laser Electron Accelerator, Phys. Rev. Lett. 43, 267 (1979).
  2. S. Semushin and V. Malka, High density gas jet nozzle design for laser target production, Review of Scientific Instruments 72, 2961 (2001).
  3. K. Schmid and L. Veisz, Supersonic gas jets for laser-plasma experiments, Review of Scientific Instruments 83, 053304 (2012).
  4. J. Ulbricht, G. Clausnitzer, and G. Graw, High density windowless gas target, Nuclear Instruments and Methods 102, 93 (1972).
  5. G. Bittner, W. Kretschmer, and W. Schuster, A windowless high-density gas target for nuclear scattering experiments, Nuclear Instruments and Methods 167, 1 (1979).
  6. M. Treichel, R. Isenbügel, and N. Marquardt, A differentially pumped supersonic jet gas target for low-energy nuclear reaction experiments, Nuclear Instruments and Methods in Physics Research 212, 101 (1983).
  7. W. Gaede, Die Diffusion der Gase durch Quecksilberdampf bei niederen Drucken und die Diffusionsluftpumpe, Annalen der Physik 351, 357 (1915).
  8. R. D. Zucker and O. Biblarz, Fundamentals of Gas Dynamics, 2nd ed. (John Wiley & Sons Inc, Hoboken, NJ, 2002).
  9. I. Andriyash, hightower8083/axiprop (2024).
  10. J. W. Goodman, Introduction to Fourier Optics (Roberts and Company Publishers, 2005).
  11. M. V. Ammosov, N. B. Delone, and V. P. Krainov, Tunnel ionization of complex atoms and of atomic ions in an alternating electromagnetic field, Soviet Journal of Experimental and Theoretical Physics 64, 1191 (1986).
  12. J. Primot and L. Sogno, Achromatic three-wave (or more) lateral shearing interferometer, J. Opt. Soc. Am. A, JOSAA 12, 2679 (1995).
  13. J. Primot and N. Guérineau, Extended Hartmann test based on the pseudoguiding property of a Hartmann mask completed by a phase chessboard, Appl. Opt., AO 39, 5715 (2000).
  14. J. U. Kim, N. Hafz, and H. Suk, Electron trapping and acceleration across a parabolic plasma density profile, Phys. Rev. E 69, 026409 (2004).

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