Intensity-correlation measurements allow access to nanostructural information on a range of ordered and disordered materials beyond traditional paircorrelation methods. In real space, this information can be expressed in terms of a pair-angle distribution function (PADF) which encodes three- and four-body distances and angles. To date, correlation-based techniques have not been applied to the analysis of microstructural effects, such as preferred orientation, which are typically investigated by texture analysis. Preferred orientation is regarded as a potential source of error in intensity-correlation experiments and complicates interpretation of the results. Here, the theory of preferred orientation in intensity-correlation techniques is developed, connecting it to the established theory of texture analysis. The preferred-orientation effect is found to scale with the number of crystalline domains in the beam, surpassing the nanostructural signal when the number of domains becomes large. Experimental demonstrations are presented of the orientation-dominant and nanostructure-dominant cases using PADF analysis. The results show that even minor deviations from uniform orientation produce the strongest angular correlation signals when the number of crystalline domains in the beam is large.
Funding
We acknowledge the funding support for AM, CD, TG and PB from the Australian Research Council Discovery Project grant (DP190103027). This research was supported by an Australian Institute of Nuclear Science and Engineering (AINSE Ltd) Early Career Researcher Grant (ECRG) to JB. We also acknowledge the funding support for BA, CD and PB from the Australian Research Council Center of Excellence in Advanced Molecular Imaging (CE140100011), www.imagingcoe.org.
History
Publication Date
2022-03-01
Journal
IUCrJ
Volume
9
Issue
2
Pagination
12p. (p. 231-242)
Publisher
International Union of Crystallography (IUCr)
ISSN
2052-2525
Rights Statement
This is an open-access article distributed under the terms of the Creative Commons Attribution (CC-BY) Licence, which permits unrestricted use, distribution, and reproduction in any medium, provided the original authors and source are cited.