Electron-beam induced damage process for Ca2Na2Nb5O16 nanosheets

Authors
Choi, HaneulLee, GwangyeobRoh, Jong WookPark, Jin-WooChang, Hye Jung
Issue Date
2022-08
Publisher
Institute of Physics Publishing
Citation
Nanotechnology, v.33, no.32
Abstract
Dielectric two-dimensional oxide nanosheets are attractive because of their thermal stability and high-k property. However, their atomic structure characterization has been limited since they are easily degraded by electron-beams. This study aimed to investigate the electron-beam induced damage mechanisms for exfoliated Ca2Na2Nb5O16 (CNNO) nanosheets. Knock-on damage dominantly occurred at high voltages, leaving short-range order in the final amorphous structure. On the other hand, a series of chemical reactions predominantly occurred at low voltages, resulting in random elemental loss and a fully disordered amorphous structure. This radiolysis was facilitated by insulated CNNO nanosheets that contained a large number of dangling bonds after the chemical solution process. The radiolysis damage kinetics was faster than knock-on damage and induced more elemental loss. Based on our understanding of the electron beam-induced degradation, atomic-scale imaging of the CNNO nanosheets was successfully performed using Cs-corrected scanning transmission electron microscopy at 300 keV with a decreased beam current. This result is of particular significance because understanding of electron-beam damage in exfoliated and insulating 2D oxide sheets could improve identification of their atomic structure using electron microscopy techniques and lead to a practical guide for further extensive characterization of doped elements and layered structures to improve their properties.
Keywords
RADIATION-DAMAGE; TITANIA NANOSHEETS; OXIDE; NANOMATERIALS; ENHANCEMENT; PHASE; LAYER; 2D nanosheets; perovskite oxide; radiation damage; transmission electron microscope
ISSN
0957-4484
URI
https://pubs.kist.re.kr/handle/201004/114846
DOI
10.1088/1361-6528/ac6bae
Appears in Collections:
KIST Article > 2022
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