Tilting and Rotational Motions of Silver Halide Crystal with Diffracted X-ray Blinking

Overview

Journal Sci Rep

Specialty Science

Date 2021 Mar 6

PMID 33674698

Citations 9

Authors

Masahiro Kuramochi

Hiroki Omata

Masaki Ishihara

Sander O Hanslin

Masaichiro Mizumaki

Naomi Kawamura

Hitoshi Osawa

Motohiro Suzuki

Kazuhiro Mio

Hiroshi Sekiguchi

Yuji C Sasaki

Affiliations

Soon will be listed here.

Abstract

The dynamic properties of crystalline materials are important for understanding their local environment or individual single-grain motions. A new time-resolved observation method is required for use in many fields of investigation. Here, we developed in situ diffracted X-ray blinking to monitor high-resolution diffraction patterns from single-crystal grains with a 50 ms time resolution. The diffraction spots of single grains of silver halides and silver moved in the θ and χ directions during the photolysis chemical reaction. The movements of the spots represent tilting and rotational motions. The time trajectory of the diffraction intensity reflecting those motions was analysed by using single-pixel autocorrelation function (sp-ACF). Single-pixel ACF analysis revealed significant differences in the distributions of the ACF decay constants between silver halides, suggesting that the motions of single grains are different between them. The rotational diffusion coefficients for silver halides were estimated to be accurate at the level of approximately 0.1 to 0.3 pm/s. Furthermore, newly formed silver grains on silver halides correlated with their ACF decay constants. Our high-resolution atomic scale measurement-sp-ACF analysis of diffraction patterns of individual grains-is useful for evaluating physical properties that are broadly applicable in physics, chemistry, and materials science.

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