Elements of a dielectric laser accelerator

TL;DR

This paper demonstrates key components of dielectric laser accelerators, including energy doubling, dephasing limit overcoming, and beam focusing, paving the way for compact, scalable particle accelerators using optical frequencies.

Contribution

It introduces novel methods for phase control, energy gain enhancement, and beam focusing in dielectric laser accelerators, advancing their scalability and practical implementation.

Findings

Achieved phase-controlled doubling of electron energy gain from 0.7 to 1.4 keV.

Overcame dephasing limit, increasing energy gain to 10% of initial energy.

Demonstrated sub-200 micron focal length transverse focusing.

Abstract

The widespread use of high energy particle beams in basic research, medicine and coherent X-ray generation coupled with the large size of modern radio frequency (RF) accelerator devices and facilities has motivated a strong need for alternative accelerators operating in regimes outside of RF. Working at optical frequencies, dielectric laser accelerators (DLAs) - transparent laser-driven nanoscale dielectric structures whose near fields can synchronously accelerate charged particles - have demonstrated high-gradient acceleration with a variety of laser wavelengths, materials, and electron beam parameters, potentially enabling miniaturized accelerators and table-top coherent x-ray sources. To realize a useful (i.e. scalable) DLA, crucial developments have remained: concatenation of components including sustained phase synchronicity to reach arbitrary final energies as well as deflection and focusing elements to keep the beam well collimated along the design axis. Here, all of these elements are demonstrated with a subrelativistic electron beam. In particular, by creating two interaction regions via illumination of a nanograting with two spatio-temporally separated pulsed laser beams, we demonstrate a phase-controlled doubling of electron energy gain from 0.7 to 1.4 keV (2.5 percent to 5 percent of the initial beam energy) and through use of a chirped grating geometry, we overcome the dephasing limit of 25 keV electrons, increasing their energy gains to a laser power limited 10 percent of their initial energy. Further, optically-driven transverse focusing of the electron beam with focal lengths below 200 microns is achieved via a parabolic grating geometry. These results lay the cornerstone for future miniaturized phase synchronous vacuum-structure-based accelerators.