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Comparison of STEM EELS Spectrum Imaging vs EFTEM Spectrum Imaging

Published online by Cambridge University Press:  02 July 2020

J.A. Hunt
Affiliation:
Gatan Research & Development, 5933 Coronado Lane, Pleasanton, CA94588, USA
G. Kothleitner
Affiliation:
Gatan Research & Development, 5933 Coronado Lane, Pleasanton, CA94588, USA
R. Harmon
Affiliation:
Gatan Research & Development, 5933 Coronado Lane, Pleasanton, CA94588, USA
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Extract

Electron energy-loss spectroscopy (EELS) in the transmission electron microscope (TEM) analyzes the energy distribution of the probe electrons after they have lost energy within the sample. The resultant energy-losses are characteristic of elemental, chemical, and dielectric properties and are typically measured in one of two ways. Parallel-detection EELS spectrometers (PEELS) acquire large energy ranges of the energy-loss spectrum simultaneously for rapid acquisition of spectral data at a single area. In contrast, the energy filtering TEM (EFTEM) acquires only a single energy band at once, but does so for thousands or even millions of image pixels simultaneously.

Spectrum imaging (SI) involves acquisition of detailed spectroscopic data sufficient for rigorous analysis at each pixel in a digital image. (Fig. la) A STEM EELS spectrum image “data cube” can be acquired by stepping a focused electron probe to each pixel and filling the spectrum image one spectrum at a time.

Type
Compositional Imaging and Spectroscopy
Copyright
Copyright © Microscopy Society of America

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