Single-Pixel Imaging in Space and Time with Optically Modulated Free Electrons

journal article in Web of Science

English

Single-pixel imaging, originally developed in light well as probing with light wavelengths undetectable by conventional multi-pixel detectors. However, the spatial resolution of optics-based single-pixel microscopy is limited by diffraction to hundreds of nanometers. Here, we propose an implementation of single-pixel imaging relying on attainable modifications of currently available ultrafast electron microscopes in which optically modulated electrons are used instead of photons to achieve subnanometer spatially and temporally resolved single-pixel imaging. We simulate electron beam profiles generated by interaction with the optical field produced by an externally programmable spatial light modulator and demonstrate the feasibility of the method by showing that the sample image and its temporal evolution can be reconstructed using realistic imperfect illumination patterns. Electron single-pixel imaging holds strong potential for application in low-dose probing of beam-sensitive biological and molecular samples, including rapid screening during in situ experiments.

single-pixel imaging; electron microscopy; electron beam shaping; electron; light interaction; ultrafast dynamics

KONEČNÁ, A.; ROTTUNO, E.; GRILLO, V.; DE ABAJO, F.; VANACORE, G.

19. 4. 2023

American Chemical Society

2330-4022

ACS Photonics

10

5

United States of America

1463

1472

10

https://pubs.acs.org/doi/full/10.1021/acsphotonics.3c00047

http://hdl.handle.net/11012/213662