Imaging atomic motion of light elements in 2D materials with 30 kV electron microscopy

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Abstract

Scanning transmission electron microscopy (STEM) is the most widespread adopted tool for atomic scale characterization of two-dimensional (2D) materials. However, damage free imaging of 2D materials with electrons has remained problematic even with powerful low-voltage 60 kV-microscopes. An additional challenge is the observation of light elements in combination with heavy elements, particularly when recording fast dynamical phenomena. Here, we demonstrate that 2D WS2 suffers from electron radiation damage during 30 kV-STEM imaging, and we capture beam-induced defect dynamics in real-time by atomic electrostatic potential imaging using integrated differential phase contrast (iDPC)-STEM. The fast imaging of atomic electrostatic potentials with iDPC-STEM reveals the presence and motion of single sulfur atoms near defects and edges in WS2 that are otherwise invisible at the same imaging dose at 30 kV with conventional annular dark-field STEM, and has a vast speed and data processing advantage over electron detector camera based STEM techniques like electron ptychography.

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APA

De Graaf, S., Ahmadi, M., Lazić, I., Bosch, E. G. T., & Kooi, B. J. (2021). Imaging atomic motion of light elements in 2D materials with 30 kV electron microscopy. Nanoscale, 13(48), 20683–20691. https://doi.org/10.1039/d1nr06614e

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