Sampling volumes in powder diffraction experiments.

Alican  Noyan; Cevdet Noyan

doi:10.1017/S0885715624000484

Sampling volumes in powder diffraction experiments.

Alican Noyan, Cevdet Noyan

Academy for AI, Games & Media

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Abstract

We present a simple analytical formalism based on the Lorentz-Scherrer equation and Bernoulli statistics for estimating the fraction of crystallites (and the associated uncertainty parameters) contributing to all finite Bragg peaks of a typical powder pattern obtained from a static polycrystalline sample. We test and validate this formalism using numerical simulations, and show that they can be applied to experiments using monochromatic or polychromatic (pink-beam) radiation. Our results show that enhancing the sampling efficiency of a given powder diffraction experiment for such samples requires optimizing the sum of the multiplicities of reflections included in the pattern along with the wavelength used in acquiring the pattern. Utilizing these equations in planning powder diffraction experiments for sampling efficiency is also discussed.

Original language	English
Journal	Powder Diffraction
Volume	2024
DOIs	https://doi.org/10.1017/S0885715624000484
Publication status	Published - 2024

Keywords

powder diffraction
sampling statistics
Lorentz sampling equation
Scherrer equation

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10.1017/S0885715624000484Licence: CC BY-NC-ND

Noyan sampling-volumes-in-powder-diffraction-experimentsFinal published version, 1 MBLicence: CC BY-NC-ND

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title = "Sampling volumes in powder diffraction experiments.",

abstract = "We present a simple analytical formalism based on the Lorentz-Scherrer equation and Bernoulli statistics for estimating the fraction of crystallites (and the associated uncertainty parameters) contributing to all finite Bragg peaks of a typical powder pattern obtained from a static polycrystalline sample. We test and validate this formalism using numerical simulations, and show that they can be applied to experiments using monochromatic or polychromatic (pink-beam) radiation. Our results show that enhancing the sampling efficiency of a given powder diffraction experiment for such samples requires optimizing the sum of the multiplicities of reflections included in the pattern along with the wavelength used in acquiring the pattern. Utilizing these equations in planning powder diffraction experiments for sampling efficiency is also discussed.",

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year = "2024",

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journal = "Powder Diffraction",

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T1 - Sampling volumes in powder diffraction experiments.

AU - Noyan, Alican

AU - Noyan, Cevdet

PY - 2024

Y1 - 2024

N2 - We present a simple analytical formalism based on the Lorentz-Scherrer equation and Bernoulli statistics for estimating the fraction of crystallites (and the associated uncertainty parameters) contributing to all finite Bragg peaks of a typical powder pattern obtained from a static polycrystalline sample. We test and validate this formalism using numerical simulations, and show that they can be applied to experiments using monochromatic or polychromatic (pink-beam) radiation. Our results show that enhancing the sampling efficiency of a given powder diffraction experiment for such samples requires optimizing the sum of the multiplicities of reflections included in the pattern along with the wavelength used in acquiring the pattern. Utilizing these equations in planning powder diffraction experiments for sampling efficiency is also discussed.

AB - We present a simple analytical formalism based on the Lorentz-Scherrer equation and Bernoulli statistics for estimating the fraction of crystallites (and the associated uncertainty parameters) contributing to all finite Bragg peaks of a typical powder pattern obtained from a static polycrystalline sample. We test and validate this formalism using numerical simulations, and show that they can be applied to experiments using monochromatic or polychromatic (pink-beam) radiation. Our results show that enhancing the sampling efficiency of a given powder diffraction experiment for such samples requires optimizing the sum of the multiplicities of reflections included in the pattern along with the wavelength used in acquiring the pattern. Utilizing these equations in planning powder diffraction experiments for sampling efficiency is also discussed.

KW - powder diffraction

KW - sampling statistics

KW - Lorentz sampling equation

KW - Scherrer equation

U2 - 10.1017/S0885715624000484

DO - 10.1017/S0885715624000484

M3 - Article

SN - 0885-7156

VL - 2024

JO - Powder Diffraction

JF - Powder Diffraction

ER -

Sampling volumes in powder diffraction experiments.

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Keywords

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