Observation of Plasma Bubble Structures in a GeV Laser-Plasma Accelerator

Abstract

We measure characteristics of plasma bubbles in GeV-class laser-plasma accelerators (LPAs) using Faraday rotation diagnostics. We extend these techniques, previously demonstrated for LPAs in atmospheric density plasmas (electron density ne >1019 cm-3), to LPAs in low-density plasmas (ne ≈ 5×1017 cm-3), in which plasma bubbles are 5 times larger, and correspondingly easier to visualize in detail. The signals show ≈ 0.5 rotation streaks of opposite sign separated by 50 μm, consistent with bubble diameter; no on-axis rotation; streaks length consistent with transverse probe pulse duration (180 μm for 500 fs pulse length, and 600 μm for 2 ps pulse length). We utilized an anamorphic imaging system to obtain a wide longitudinal field of view (>1 cm) and a high transverse resolution (<9 μm). We also demonstrated that Faraday rotation signals are sensitive to the stages of acceleration processes using extended 2D Finite Difference Time Domain (FDTD) simulation.