Probing the interaction range of electron beam-induced etching in STEM by a non-contact electron beam

Stefan Manuel Noisternig, Christian Rentenberger, Christoph Gammer, H. Peter Karnthaler, Jani Kotakoski

Publications: Contribution to journalArticlePeer Reviewed

Abstract

Beside its main purpose as a high-end tool in material analysis reaching the atomic scale for structure, chemical and electronic properties, aberration-corrected scanning transmission electron microscopy (STEM) is increasingly used as a tool to manipulate materials down to that very same scale. In order to obtain exact and reproducible results, it is essential to consider the interaction processes and interaction ranges between the electron beam and the involved materials. Here, we show in situ that electron beam-induced etching in a low-pressure oxygen atmosphere can extend up to a distance of several nm away from the Ångström-size electron beam, usually used for probing the sample. This relatively long-range interaction is related to beam tails and inelastic scattering involved in the etching process. To suppress the influence of surface diffusion, we measure the etching effect indirectly on isolated nm-sized holes in a 2 nm thin amorphous carbon foil that is commonly used as sample support in STEM. During our experiments, the electron beam is placed inside the nanoholes so that most electrons cannot directly participate in the etching process. We characterize the etching process from measuring etching rates at multiple nanoholes with different distances between the hole edge and the electron beam.

Original languageEnglish
Article number114019
Number of pages10
JournalUltramicroscopy
Volume265
DOIs
Publication statusPublished - Nov 2024

Austrian Fields of Science 2012

  • 103042 Electron microscopy

Keywords

  • Amorphous carbon
  • Beam tails
  • Chemical etching
  • Electron irradiation
  • Nanoholes
  • Oxygen dissociation

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