Imaging atomic-scale chemistry from fused multi-modal electron microscopy

Imaging atomic-scale chemistry from fused multi-modal electron microscopy

Efforts to map atomic-scale chemistry at low doses with minimal noise using electron microscopes are fundamentally limited by inelastic interactions. Here, fused multi-modal electron microscopy offers high signal-to-noise ratio (SNR) recovery of material chemistry at nano- and atomic-resolution by c...

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Veröffentlicht in:npj computational materials 2022-01, Vol.8 (1), p.1-8, Article 16
Hauptverfasser: Schwartz, Jonathan, Di, Zichao Wendy, Jiang, Yi, Fielitz, Alyssa J., Ha, Don-Hyung, Perera, Sanjaya D., El Baggari, Ismail, Robinson, Richard D., Fessler, Jeffrey A., Ophus, Colin, Rozeveld, Steve, Hovden, Robert
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Sprache:eng
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639/301/930/12
639/301/930/328/2082
639/766/930/2735
639/766/930/328/2082
characterization and analytical techniques
Characterization and Evaluation of Materials
Chemistry
Chemistry and Materials Science
Computational Intelligence
Elastic scattering
Electron energy loss spectroscopy
Electron microscopes
Electron microscopy
Energy dissipation
imaging techniques
Inelastic scattering
MATERIALS SCIENCE
Mathematical and Computational Engineering
Mathematical and Computational Physics
Mathematical Modeling and Industrial Mathematics
Microscopes
Microscopy
Nanomaterials
Nanotechnology
Signal to noise ratio
Theoretical
transmission electron microscopy
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Beschreibung
Zusammenfassung:Efforts to map atomic-scale chemistry at low doses with minimal noise using electron microscopes are fundamentally limited by inelastic interactions. Here, fused multi-modal electron microscopy offers high signal-to-noise ratio (SNR) recovery of material chemistry at nano- and atomic-resolution by coupling correlated information encoded within both elastic scattering (high-angle annular dark-field (HAADF)) and inelastic spectroscopic signals (electron energy loss (EELS) or energy-dispersive x-ray (EDX)). By linking these simultaneously acquired signals, or modalities, the chemical distribution within nanomaterials can be imaged at significantly lower doses with existing detector hardware. In many cases, the dose requirements can be reduced by over one order of magnitude. This high SNR recovery of chemistry is tested against simulated and experimental atomic resolution data of heterogeneous nanomaterials.
ISSN:2057-3960
2057-3960
DOI:10.1038/s41524-021-00692-5