Zero vector potential mechanism of attosecond absorption in strongly relativistic plasmas

TL;DR

This paper introduces a novel relativistic mechanism involving zero vector potential points that explains fast electron generation at plasma boundaries during intense laser interactions, with implications for attosecond pulse generation and advanced plasma applications.

Contribution

It reveals a new relativistic electron generation mechanism based on zero vector potential points, differing from classical models, and demonstrates its impact on plasma interaction dynamics.

Findings

Fast electron energy scales with plasma density.

Zero vector potential points dominate electron injection.

Mechanism enables generation of attosecond electron bunches.

Abstract

The understanding of the physics of lasermatter interactions in the strongly relativistic regime is of fundamental importance. In this article, a new mechanism of fast electron generation at the vacuum-solid boundary of intense laser pulse interaction with overdense plasma is described. It is one that has no analogue in classical, non-relativistic laser-plasma interactions. Here, conclusive proof is provided that the key contribution to the fast electron generation is given by the zero points of the vector potential. We demonstrate that the new mechanism leads to scalings for the fast electron energy, which explicitly depend on the plasma density, thus providing a new insight into relativistic laser-matter interaction. Furthermore, it is shown that this new mechanism provides the dominant contribution to the interaction by the injection of energy into the overdense plasma delivered by attosecondduration electron bunches. This new understanding will allow the future generation of a single ultra-bright attosecond X-ray pulse by suitable control of the laser pulse polarization [1]-[7]. This process will also allow single pulse attosecond electron bunches to be generated that can be further accelerated in laser wakefield accelerators [8]-[10]. Other applications that will benefit from this new insight include laser driven ion accelerators [11]-[15], fast ignition inertial confinement fusion [16]-[18] as well as fundamental studies at the intensity frontier [19]-[20].