Study of near-GeV acceleration of electrons in a non-linear plasma wave driven by a self-guided laser pulse

S Kneip ,Oleg Cheklov ,C J Hooker ,J Schreiber ,D Urner ,Frederico Fiúza ,G Doucas ,P P Rajeev ,K Krushelnick ,R J Clarke ,L O Silva ,C A J Palmer ,S R Nagel ,K Ta Phuoc ,Klaus Ertel ,P S Foster ,Matthew Streeter ,S F Martins ,S P D Mangles ,E J Divall ,Nicolas Delerue ,R Heathcote ,C Bellei ,S Hawkes ,Ricardo Fonseca ,Jorge Vieira ,Z Najmudin

doi:10.1088/0741-3335/53/1/014008

Study of near-GeV acceleration of electrons in a non-linear plasma wave driven by a self-guided laser pulse

S Kneip , Oleg Cheklov + Show 25 more

https://doi.org/10.1088/0741-3335/53/1/014008

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Journal: Plasma Physics and Controlled Fusion	Publication Date: Dec 16, 2010
Citations: 12

Affiliation: Imperial College London, Rutherford Appleton Laboratory, University of Oxford, Optical Sciences (United States), University of Michigan–Ann Arbor, Laboratoire d'Optique Appliquée, École Polytechnique, École Nationale Supérieure de Techniques Avancées, Institut Polytechnique de Paris

#Self-guided Laser Pulse #Peak Electron Energy + Show 8 more

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Abstract

Electrons are accelerated up to 0.8 GeV in a self-injecting laser wakefield accelerator driven at a plasma density of 5.5 × 1018 cm−3 by a 10 J, 55 fs, 800 nm laser pulse in the blow-out regime. The electron beam stability is correlated with the laser focal spot pointing stability and depends on the target alignment. Variations of the laser pulse energy, focal spot size and energy within the full width at half maximum have little effect on the electron beam profile (stability) but impact the electron energy (stability). The peak electron energy is higher than expected for the initial vacuum intensity. This is evidence for intensity amplification which also explains the observation of polyenergetic beamlets.

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