Theory and simulations of the angular momentum transfer from swift electrons to spherical nanoparticles in STEM

TL;DR

This paper develops a classical-electrodynamics model and numerical method to analyze how swift electrons transfer angular momentum to spherical nanoparticles in STEM, revealing dependencies on size, speed, and impact parameters.

Contribution

It introduces a novel theoretical and computational framework for calculating angular momentum transfer from electrons to nanoparticles in STEM, extending understanding beyond linear momentum.

Findings

Angular momentum transfer is perpendicular to the system's plane of symmetry.

Transfer increases with nanoparticle radius and decreases with electron speed and impact parameter.

Electric contribution dominates over magnetic, except at very high electron speeds.

Abstract

Electron beams in scanning transmission electron microscopy (STEM) exert forces and torques on study samples, with magnitudes that allow the controlled manipulation of nanoparticles (a technique called electron tweezers). Related theoretical research has mostly focused on the study of forces and linear momentum transfers from swift electrons (like those used in STEM) to nanoparticles. However, theoretical research on the rotational aspects of the interaction would benefit not only the development of electron tweezers, but also other fields within electron microscopy such as electron vortices. Starting from a classical-electrodynamics description, we present a theoretical model, alongside an efficient numerical methodology, to calculate the angular momentum transfer from a STEM swift electron to a spherical nanoparticle. We show simulations of angular momentum transfers to aluminum, gold, and bismuth nanoparticles of different sizes. We found that the transferred angular momentum is always perpendicular to the system's plane of symmetry, displaying a constant direction for all the cases considered. In the simulations, the angular momentum transfer increased with the radius of the nanoparticle, but decreased as the speed of the electron or the impact parameter increased. Also, the electric contribution to the angular momentum transfer dominated over the magnetic one, being comparable only for high electron's speeds (greater than 90% of the speed of light). Additionally, for nanoparticles with 1 nm radius of the studied materials, we found validity criteria for the small-particle approximation (in which the nanoparticle is modeled as an electric point dipole). We believe that these findings contribute to the understanding of rotational aspects present in STEM experiments, and might be useful for further developments in electron tweezers and other electron microscopy related techniques.