Electron Acceleration During the Mode Transition from Laser Wakefield to Plasma Wakefield Acceleration with a Dense-Plasma Wall

The wake bubble expansion and contraction by adding a dense-plasma wall in the background plasma during the mode transition from laser wakefield to plasma wakefield acceleration is investigated by particle-in-cell simulations.The electrons are injected continuously into the cavity until the lateral bubble size equals the inner diameter of the wall.The injected electron bunch from the laser wakefield acceleration(LWFA) scheme is quasi phase-stably accelerated forward because of the longitudinal contraction of the bubble.After the laser pulse is depleted completely,the electron bunch generated from the LWFA scheme drives a plasma wakefield.The electrons remaining in the channel are trapped and accelerated by the plasma wakefield.Ultimately,two energetic electron bunches with a narrow energy spread and low emittance are obtained.     

Wakefield Resonant Excitation by Intense Laser Pulse in Capillary Plasma

The laser-induced plasma wakefield in a capillary is investigated on the basis of a simple two-dimensional analytical model. It is shown that as an intense laser pulse reshaped by the capillary wall propagates in capillary plasma, it resonantly excites a strong wakefield if a suitable laser pulse width and capillary radius are chosen for a certain plasma density. The dependence of the laser width and capillary radius on the plasma density for resonance conditions is considered. The wakefield amplitude and longitudinal scale of bubbles in capillary plasma are much larger than those in unbounded plasma, so the capillary guided plasma wakefield is more favorable to electron acceleration.