Non-linear Ion-wake Excitation by Ultra-relativistic Electron Wakefields

TL;DR

This paper models the excitation of a non-linear ion-wake by ultra-relativistic electron wakefields, revealing a cylindrical ion-soliton structure that can be utilized for positron acceleration, supported by PIC simulations.

Contribution

It introduces a new model of non-linear ion-wake excitation by electron wakefields and explores its application in positron acceleration using PIC simulations.

Findings

Ion-wake forms a cylindrical ion-soliton structure.

The ion-soliton can be used for positron acceleration.

Simulation confirms the stability and structure of the ion-wake.

Abstract

The excitation of a non-linear ion-wake by a train of ultra-relativistic electron bubble wake [1]-[8] is modeled. The ion-wake is shown to be a driven non-linear ion-acoustic wave in the form of a cylindrical ion-soliton [11]-[14]. The phases of the oscillating radial electric fields of the slowly-propagating [21] electron bubble is asymmetric in time and excites time-averaged inertial ion motion radially. The electron compression in the back of the bubble sucks-in the ions and the space-charge within the bubble cavity expels them, driving a cylindrical ion-soliton structure with on-axis and bubble-edge density-spikes [5][6]. Once formed, the channel-edge density-spike is driven radially outwards by the thermal pressure of the wake energy [12]. Its channel-like structure due to the flat-residue left behind by the propagating ion-soliton, is independent of the energy-source driving the bubble [3][4] electron wake. We explore the use of the partially- filled channel formed by the cylindrical ion-soliton for a novel regime of positron acceleration [18]. OSIRIS PIC [25] simulations are used to study the ion-wake soliton structure, its driven propagation and its use for positron acceleration.