Ultra-high resolution electron microscopy

Mark P. Oxley, Andrew R. Lupini, Stephen J. Pennycook

Research output: Contribution to journalReview articlepeer-review

20 Scopus citations

Abstract

The last two decades have seen dramatic advances in the resolution of the electron microscope brought about by the successful correction of lens aberrations that previously limited resolution for most of its history. We briefly review these advances, the achievement of sub-Ångstrom resolution and the ability to identify individual atoms, their bonding configurations and even their dynamics and diffusion pathways. We then present a review of the basic physics of electron scattering, lens aberrations and their correction, and an approximate imaging theory for thin crystals which provides physical insight into the various different imaging modes. Then we proceed to describe a more exact imaging theory starting from Yoshioka's formulation and covering full image simulation methods using Bloch waves, the multislice formulation and the frozen phonon/quantum excitation of phonons models. Delocalization of inelastic scattering has become an important limiting factor at atomic resolution. We therefore discuss this issue extensively, showing how the full-width-half-maximum is the appropriate measure for predicting image contrast, but the diameter containing 50% of the excitation is an important measure of the range of the interaction. These two measures can differ by a factor of 5, are not a simple function of binding energy, and full image simulations are required to match to experiment. The Z-dependence of annular dark field images is also discussed extensively, both for single atoms and for crystals, and we show that temporal incoherence must be included accurately if atomic species are to be identified through matching experimental intensities to simulations. Finally we mention a few promising directions for future investigation.

Original languageEnglish
Article number026101
JournalReports on Progress in Physics
Volume80
Issue number2
DOIs
StatePublished - Feb 2017

Bibliographical note

Publisher Copyright:
© 2016 IOP Publishing Ltd.

Funding

This research was supported by the Office of Basic Energy Sciences, Materials Sciences and Engineering Division, US Department of Energy (MPO, ARL).

FundersFunder number
Office of Basic Energy Sciences
US Department of Energy
Division of Materials Sciences and Engineering

    Keywords

    • aberration correction
    • delocalization of inelastic scattering
    • electron scattering
    • image simulation
    • scanning transmission electron microscopy

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