A laser–plasma accelerator producing monoenergetic electron beams

Abstract

Particle accelerators are used in a wide variety of fields, ranging from medicine and biology to high-energy physics. The accelerating fields in conventional accelerators are limited to a few tens of MeV m^-1, owing to material breakdown at the walls of the structure. Thus, the production of energetic particle beams currently requires large-scale accelerators and expensive infrastructures. Laser–plasma accelerators¹ have been proposed as a next generation of compact accelerators because of the huge electric fields they can sustain^2,3,4,5 (>100 GeV m^-1). However, it has been difficult to use them efficiently for applications because they have produced poor-quality particle beams with large energy spreads^{2,3,4,5,6,7,8,9,10}, owing to a randomization of electrons in phase space. Here we demonstrate that this randomization can be suppressed and that the quality of the electron beams can be dramatically enhanced. Within a length of 3 mm, the laser drives a plasma bubble¹¹ that traps and accelerates plasma electrons. The resulting electron beam is extremely collimated and quasi-monoenergetic, with a high charge of 0.5 nC at 170 MeV.