Femtosecond laser-induced plasma filaments for beam-driven plasma wakefield acceleration

M. Galletti; L. Crincoli; R. Pompili; L. Verra; F. Villa; R. Demitra; A. Biagioni; A. Zigler; M. Ferrario

doi:10.1103/physreve.111.025202

Femtosecond laser-induced plasma filaments for beam-driven plasma wakefield acceleration

M. Galletti
, L. Crincoli
, R. Pompili
, L. Verra
, F. Villa
, R. Demitra
, A. Biagioni
, A. Zigler
, M. Ferrario

Racah Institute of Physics

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

We describe the generation of plasma filaments for application in plasma-based particle accelerators. The complete characterization of a plasma filament generated by a low-energy self-guided femtosecond laser pulse is studied experimentally and theoretically in a low-pressure nitrogen gas environment. For this purpose, we adopted a spectroscopic methodology to measure the plasma density and electron temperature. In addition to this, we also employed a side-imaging technique to retrieve the plasma column sizes (length and diameter). The measurements show the stable generation of a ≈4-cm-long plasma filament with ≈300μm diameter. The peak plasma density and temperature are ne≈1016cm-3 and Te≈1.3eV, respectively, with a decay time of approximately 8 ns. We show that the experimental results are in agreement with numerical simulations in terms of filament size and density decay time.

Original language	English
Article number	025202
Journal	Physical Review Accelerators and Beams
Volume	28
Issue number	2
DOIs	https://doi.org/10.1103/physreve.111.025202
State	Published - Feb 2025

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© 2025 American Physical Society.

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10.1103/physreve.111.025202

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abstract = "We describe the generation of plasma filaments for application in plasma-based particle accelerators. The complete characterization of a plasma filament generated by a low-energy self-guided femtosecond laser pulse is studied experimentally and theoretically in a low-pressure nitrogen gas environment. For this purpose, we adopted a spectroscopic methodology to measure the plasma density and electron temperature. In addition to this, we also employed a side-imaging technique to retrieve the plasma column sizes (length and diameter). The measurements show the stable generation of a ≈4-cm-long plasma filament with ≈300μm diameter. The peak plasma density and temperature are ne≈1016cm-3 and Te≈1.3eV, respectively, with a decay time of approximately 8 ns. We show that the experimental results are in agreement with numerical simulations in terms of filament size and density decay time.",

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AU - Galletti, M.

AU - Crincoli, L.

AU - Pompili, R.

AU - Verra, L.

AU - Villa, F.

AU - Demitra, R.

AU - Biagioni, A.

AU - Zigler, A.

AU - Ferrario, M.

PY - 2025/2

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Femtosecond laser-induced plasma filaments for beam-driven plasma wakefield acceleration

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