Crossed laser phase plates for transmission electron microscopy

TL;DR

This paper introduces crossed laser phase plates (XLPP) for transmission electron microscopy, enhancing image contrast and suppressing diffraction artifacts through a novel intersecting laser beam design, supported by theoretical modeling, simulations, and prototype experiments.

Contribution

It proposes the innovative XLPP design, providing a theoretical framework, simulation analysis, and experimental validation for improved TEM imaging.

Findings

XLPP increases low-frequency information transfer.

XLPP suppresses ghost images from Kapitza-Dirac diffraction.

A simple acquisition scheme enhances image quality.

Abstract

For decades since the development of phase-contrast optical microscopy, an analogous approach has been sought for maximizing the image contrast of weakly-scattering objects in transmission electron microscopy (TEM). The recent development of the laser phase plate (LPP) has demonstrated that an amplified, focused laser standing wave provides stable, tunable phase shift to the high-energy electron beam, achieving phase-contrast TEM. Building on proof-of-concept experimental demonstrations, this paper explores design improvements tailored to biological imaging. In particular, we introduce the approach of crossed laser phase plates (XLPP): two laser standing waves intersecting in the diffraction plane of the TEM, rather than a single beam as in the current LPP. We provide a theoretical model for the XLPP inside the microscope and use simulations to quantify its effect on image formation. Using simulations, we find that the XLPP increases information transfer at low spatial frequencies while also suppressing the ghost images formed by Kapitza-Dirac diffraction of the electron beam by the laser beam. We also present a simple acquisition scheme, enabled by the XLPP, which dramatically suppresses unwanted diffraction effects. Finally, we discuss important practical considerations of XLPP design and show experimental results from a prototype. The results of this study chart the course for future developments of LPP hardware.