Theoretical and Experimental Studies on Steady-state Microbunching

TL;DR

This paper explores the theoretical and experimental aspects of steady-state microbunching (SSMB) in electron storage rings, aiming to develop high-power, high-repetition-rate coherent radiation sources for advanced photon science applications.

Contribution

It provides a comprehensive study on how to realize SSMB, characterizes the radiation from SSMB, and experimentally demonstrates its working mechanism in a real accelerator.

Findings

Successful realization of SSMB in a storage ring.

Characterization of radiation properties from SSMB.

Experimental validation of SSMB's working mechanism.

Abstract

Particle accelerators as photon sources are advanced tools in studying the structure and dynamical properties of matter. The present workhorses of these sources are storage ring-based synchrotron radiation facilities and linear accelerator-based free-electron lasers, delivering light with high repetition rate and high peak brilliance (power), respectively. The steady-state microbunching (SSMB) mechanism was proposed to bridge the gap of these two kinds of sources to generate high-average-power, high-repetition-rate coherent radiation in an electron storage ring. Such a novel light source promises new possibilities for accelerator photon science and industry applications, for example in ultra-high-energy-resolution angle-resolved photoemission spectroscopy and extreme ultraviolet lithography. The six orders of magnitude extrapolation of the electron bunch length in an SSMB storage ring compared to that of a conventional ring provides tremendous opportunities for accelerator physics research. This dissertation is devoted to the theoretical and experimental investigations of SSMB, with important results achieved. The work presented can be summarized as: first, how to realize SSMB; second, what radiation characteristics can we obtain from the formed SSMB; and third, experimentally demonstrate the working mechanism of SSMB in a real machine.