A quantitative measure of medium-range order in amorphous materials from transmission electron micrographs

R. K. Dash; P. M. Voyles; J. M. Gibson; M. M.J. Treacy; P. Keblinski

doi:10.1088/0953-8984/15/31/317

A quantitative measure of medium-range order in amorphous materials from transmission electron micrographs

R. K. Dash
, P. M. Voyles
, J. M. Gibson
, M. M.J. Treacy
, P. Keblinski

Research output: Contribution to journal › Article › peer-review

34 Scopus citations

Abstract

We propose an extension to the technique of fluctuation electron microscopy that quantitatively measures a medium-range order correlation length in amorphous materials. In both simulated images from computer-generated paracrystalline amorphous silicon models and experimental images of amorphous silicon, we find that the spatial autocorrelation function of dark-field transmission electron micrographs of amorphous materials exhibits a simple exponential decay. The decay length measures a nanometre-scale structural correlation length in the sample, although it also depends on the microscope resolution. We also propose a new interpretation of the fluctuation microscopy image variance in terms of fluctuations in local atomic pair distribution functions.

Original language	English (US)
Pages (from-to)	S2425-S2435
Journal	Journal of Physics Condensed Matter
Volume	15
Issue number	31
DOIs	https://doi.org/10.1088/0953-8984/15/31/317
State	Published - Aug 13 2003
Externally published	Yes

ASJC Scopus subject areas

General Materials Science
Condensed Matter Physics

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abstract = "We propose an extension to the technique of fluctuation electron microscopy that quantitatively measures a medium-range order correlation length in amorphous materials. In both simulated images from computer-generated paracrystalline amorphous silicon models and experimental images of amorphous silicon, we find that the spatial autocorrelation function of dark-field transmission electron micrographs of amorphous materials exhibits a simple exponential decay. The decay length measures a nanometre-scale structural correlation length in the sample, although it also depends on the microscope resolution. We also propose a new interpretation of the fluctuation microscopy image variance in terms of fluctuations in local atomic pair distribution functions.",

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AU - Dash, R. K.

AU - Voyles, P. M.

AU - Gibson, J. M.

AU - Treacy, M. M.J.

AU - Keblinski, P.

PY - 2003/8/13

Y1 - 2003/8/13

N2 - We propose an extension to the technique of fluctuation electron microscopy that quantitatively measures a medium-range order correlation length in amorphous materials. In both simulated images from computer-generated paracrystalline amorphous silicon models and experimental images of amorphous silicon, we find that the spatial autocorrelation function of dark-field transmission electron micrographs of amorphous materials exhibits a simple exponential decay. The decay length measures a nanometre-scale structural correlation length in the sample, although it also depends on the microscope resolution. We also propose a new interpretation of the fluctuation microscopy image variance in terms of fluctuations in local atomic pair distribution functions.

AB - We propose an extension to the technique of fluctuation electron microscopy that quantitatively measures a medium-range order correlation length in amorphous materials. In both simulated images from computer-generated paracrystalline amorphous silicon models and experimental images of amorphous silicon, we find that the spatial autocorrelation function of dark-field transmission electron micrographs of amorphous materials exhibits a simple exponential decay. The decay length measures a nanometre-scale structural correlation length in the sample, although it also depends on the microscope resolution. We also propose a new interpretation of the fluctuation microscopy image variance in terms of fluctuations in local atomic pair distribution functions.

UR - https://www.scopus.com/pages/publications/0042881045

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JO - Journal of Physics Condensed Matter

JF - Journal of Physics Condensed Matter

IS - 31

ER -

A quantitative measure of medium-range order in amorphous materials from transmission electron micrographs

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