Attosecond Control of Relativistic Electron Bunches using Two-Colour Fields

TL;DR

This paper demonstrates how adding a second harmonic laser pulse can precisely control relativistic electron trajectories during intense laser-matter interactions, enabling enhanced harmonic emission and advancing attosecond science.

Contribution

It introduces a method for attosecond control of electron bunches using two-color laser fields, combining experimental and simulation results to show phase-sensitive enhancements.

Findings

Significant enhancement in harmonic yield with phase control

Attosecond precision control of electron trajectories achieved

Potential for improved attosecond pulse generation in experiments

Abstract

Energy coupling during relativistically intense laser-matter interactions is encoded in the attosecond motion of strongly driven electrons at the pre-formed plasma-vacuum boundary. Studying and controlling this motion can reveal details about the microscopic processes that govern a vast array of light-matter interaction physics and applications. These include research areas right at the forefront of extreme laser-plasma science such as laser-driven ion acceleration1, bright attosecond pulse generation2,3 and efficient energy coupling for the generation and study of warm dense matter4. Here we demonstrate attosecond control over the trajectories of relativistic electron bunches formed during such interactions by studying the emission of extreme ultraviolet (XUV) harmonic radiation. We describe how the precise addition of a second laser beam operating at the second harmonic of the driving laser pulse can significantly transform the interaction by modifying the accelerating potential provided by the fundamental frequency to drive strong coherent emission. Numerical particle-in-cell code simulations and experimental observations demonstrate that this modification is extremely sensitive to the relative phase of the two beams and can lead to significant enhancements in the resulting harmonic yield. This work also reveals that the ability to control these extreme interactions with attosecond precision is an essential requirement for generation of ultra-bright, high temporal contrast attosecond radiation for atomic and molecular pump-probe experiments5,6.