Subrelativistic Alternating Phase Focusing Dielectric Laser Accelerators

TL;DR

This paper demonstrates a silicon-based dielectric laser accelerator that uses alternating phase focusing to confine and accelerate electrons over extended distances, achieving significant energy gains in a compact setup.

Contribution

It introduces a novel APF lattice design for dielectric laser accelerators, enabling long interaction lengths and substantial energy gains in a subrelativistic regime.

Findings

Achieved energy gains up to 23.7 keV in a 708 μm interaction length.

Demonstrated stable electron confinement using APF in dielectric laser accelerators.

Enhanced acceleration gradients with fractional phase drift techniques.

Abstract

We demonstrate a silicon-based electron accelerator that uses laser optical near fields to both accelerate and confine electrons over extended distances. Two dielectric laser accelerator (DLA) designs were tested, each consisting of two arrays of silicon pillars pumped symmetrically by pulse front tilted laser beams, designed for average acceleration gradients 35 and 50 MeV/m respectively. The DLAs are designed to act as alternating phase focusing (APF) lattices, where electrons, depending on the electron-laser interaction phase, will alternate between opposing longitudinal and transverse focusing and defocusing forces. By incorporating fractional period drift sections that alter the synchronous phase between $\pm 60^\circ$ off crest, electrons captured in the designed acceleration bucket experience half the peak gradient as average gradient while also experiencing strong confinement forces that enable long interaction lengths. We demonstrate APF accelerators with interaction lengths up to 708 ${\mu}$m and energy gains up to 23.7 $\pm$ 1.07 keV FWHM, a 25$\%$ increase from starting energy, demonstrating the ability to achieve substantial energy gains with subrelativistic DLA.