Abstract

Electron diffraction techniques in transmission electron microscopy (TEM) have been successfully employed for determining the unit-cell parameters of crystal phases, albeit they exhibit a limited accuracy compared with X-ray or neutron diffraction, and they often involve a tedious measurement procedure. Here, a new package for determining unit-cell parameters from a single electron diffraction pattern has been developed. The essence of the package is to reconstruct a 3D reciprocal primitive cell from a single electron diffraction pattern containing both zero-order Laue zone and high-order Laue zone reflections. Subsequently, the primitive cell can be reduced to the Niggli cell which, in turn, can be converted into the unit cell. Using both simulated and experimental patterns, we detail the working procedure and address some effects of experimental conditions (diffraction distortions, misorientation of the zone axis and the use of high-index zone axis) on the robustness and accuracy of the software developed. The feasibility of unit-cell determination of the TiO2 nanorod using this package is also demonstrated. Should the parallel-beam, nano-beam and convergent-beam modes of the TEM be used flexibly, the software can determine unit-cell parameters of unknown-structure crystallites (typically >50 nm).

Highlights

  • Unit-cell parameters and symmetry elements are two fundamental crystallographic quantities for characterizing a crystal structure

  • In order to estimate the accuracy of the cell, we separately evaluate the sum of the differences between the unit cell obtained and the standard Bravais as two figures of merit (FOM): one for unit-cell lengths of FOMa 1⁄4 100% Â ð"a þ "b þ "cÞ=3 and the other for unit-cell angles of FOM 1⁄4 100% Â ð" þ " þ " Þ=3, where "x 1⁄4 jx À x"j=jx"j defines the absolute value of the relative error of unit-cell parameters

  • We developed an analysis package to determine unit-cell parameters of crystals using a single electron diffraction pattern that contains both ZOLZ and high-order Laue zone (HOLZ) reflections

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Summary

Introduction

Unit-cell parameters and symmetry elements are two fundamental crystallographic quantities for characterizing a crystal structure. Some excellent electron diffraction software has been developed to determine unit-cell parameters, e.g. TRICE (Zou et al, 2004), TEMUC3 (Li, 2019) and QtUCP (Zhao et al, 2008) etc These analysis packages require at least two zone-axis patterns recorded by a tilt series; this limits the application of the nanosized crystallite and the electron-sensitive materials for the time-consuming crystal tilting process. We experimentally test the applicability of the software to determine the unit-cell parameters of nanocrystallites using diffraction patterns from both CBED and nano-beam electron diffraction (NBED) methods

The HOLZ ring and reciprocal-lattice layer spacing
Description of the software
Results and discussion
Unit-cell determination from a simulated pattern
Effects of experimental conditions on the unit-cell determination
Conclusions

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