Design Study of a Dielectric Laser Undulator

TL;DR

This paper explores the design and beam dynamics of dielectric laser undulators, proposing optimized focusing schemes and validating models through simulations, to enable radiation generation experiments.

Contribution

It introduces an optimized alternating phase focusing scheme for dielectric laser undulators and validates analytical models with numerical simulations.

Findings

Optimized focusing scheme enhances beam stability.

Asynchronous operation simplifies grating requirements.

Validated models facilitate future radiation experiments.

Abstract

Dielectric laser acceleration (DLA) achieves remarkable gradients from the optical near fields of a grating structure. Tilting the dielectric grating with respect to the electron beam leads to deflection forces and the DLA structure can be utilized as a microchip undulator. We investigate the beam dynamics in such structures analytically and by numerical simulations. A crucial challenge is to keep the beam focused, especially in direction of the narrow channel. An alternating phase focusing scheme is optimized for this purpose and matched lattice functions are obtained. We distinguish synchronous operation with phase jumps in the grating and asynchronous operation with a strictly periodic grating and well-designed synchronicity mismatch. Especially the asynchronous DLA undulator is a promising approach, since a simple, commercially available grating suffices for the focusing lattice design. We pave the way towards experiments of radiation generation in these structures and provide estimates of the emitted radiation wavelength and power. The analytical models are validated by numerical simulations in the dedicated DLA simulation tool DLAtrack6D and Astra, where the underlying laser fields are computed by CST Studio.