Self-guided laser wakefield acceleration beyond 1 GeV using ionization-induced injection

C E Clayton; J E Ralph; F Albert; R A Fonseca; S H Glenzer; C Joshi; W Lu; K A Marsh; S F Martins; W B Mori; A Pak; F S Tsung; B B Pollock; J S Ross; L O Silva; D H Froula

doi:10.1103/PhysRevLett.105.105003

Self-guided laser wakefield acceleration beyond 1 GeV using ionization-induced injection

Phys Rev Lett. 2010 Sep 3;105(10):105003. doi: 10.1103/PhysRevLett.105.105003. Epub 2010 Sep 1.

Authors

C E Clayton¹, J E Ralph, F Albert, R A Fonseca, S H Glenzer, C Joshi, W Lu, K A Marsh, S F Martins, W B Mori, A Pak, F S Tsung, B B Pollock, J S Ross, L O Silva, D H Froula

Affiliation

¹ Department of Electrical Engineering, University of California, Los Angeles, California 90095, USA. cclayton@ucla.edu

PMID: 20867526
DOI: 10.1103/PhysRevLett.105.105003

Abstract

The concepts of matched-beam, self-guided laser propagation and ionization-induced injection have been combined to accelerate electrons up to 1.45 GeV energy in a laser wakefield accelerator. From the spatial and spectral content of the laser light exiting the plasma, we infer that the 60 fs, 110 TW laser pulse is guided and excites a wake over the entire 1.3 cm length of the gas cell at densities below 1.5 × 10(18) cm(-3). High-energy electrons are observed only when small (3%) amounts of CO2 gas are added to the He gas. Computer simulations confirm that it is the K-shell electrons of oxygen that are ionized and injected into the wake and accelerated to beyond 1 GeV energy.