Parameterized absorptive electron scattering factors.

IF 1.9 4区材料科学 Q3 CHEMISTRY, MULTIDISCIPLINARY Acta Crystallographica Section A: Foundations and Advances Pub Date : 2024-03-01 Epub Date: 2024-01-25 DOI:10.1107/S2053273323010963

M Thomas, A Cleverley, R Beanland

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Abstract

In electron diffraction, thermal atomic motion produces incoherent scattering over a relatively wide angular range, which appears as a diffuse background that is usually subtracted from measurements of Bragg spot intensities in structure solution methods. The transfer of electron flux from Bragg spots to diffuse scatter is modelled using complex scattering factors f + if' in the Bloch wave methodology. In a two-beam Einstein model the imaginary `absorptive' scattering factor f' can be obtained by the evaluation of an integral containing f over all possible scattering angles. While more sophisticated models of diffuse scatter are widely used in the electron microscopy community, it is argued in this paper that this simple model is appropriate for current structure solution and refinement methods. The two-beam model is a straightforward numerical calculation, but even this simplistic approach can become time consuming for simulations of materials with large numbers of atoms in the unit cell and/or many incident beam orientations. Here, a parameterized form of f' is provided for 103 elements as neutral, spherical atoms that reduces calculation time considerably.

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参数化的吸收性电子散射因子。

在电子衍射中，热原子运动在相对较宽的角度范围内产生非相干散射，这种散射以漫射背景的形式出现，通常在结构求解方法中从布拉格光斑强度测量值中减去。在布洛赫波方法中，电子通量从布拉格光斑向弥散散射的转移是通过复散射因子 f + if' 来模拟的。在双光束爱因斯坦模型中，虚 "吸收 "散射因子f'可以通过对所有可能的散射角进行包含f的积分来获得。虽然电子显微镜界广泛使用更复杂的漫散射模型，但本文认为这种简单的模型适用于当前的结构求解和细化方法。双光束模型是一种直接的数值计算方法，但即使是这种简单的方法，在模拟单胞中有大量原子和/或许多入射光束方向的材料时也会变得非常耗时。在这里，我们为 103 个作为中性球形原子的元素提供了 f' 的参数化形式，从而大大减少了计算时间。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Acta Crystallographica Section A: Foundations and Advances CHEMISTRY, MULTIDISCIPLINARYCRYSTALLOGRAPH-CRYSTALLOGRAPHY

CiteScore

2.60

自引率

11.10%

发文量

419

期刊介绍： Acta Crystallographica Section A: Foundations and Advances publishes articles reporting advances in the theory and practice of all areas of crystallography in the broadest sense. As well as traditional crystallography, this includes nanocrystals, metacrystals, amorphous materials, quasicrystals, synchrotron and XFEL studies, coherent scattering, diffraction imaging, time-resolved studies and the structure of strain and defects in materials. The journal has two parts, a rapid-publication Advances section and the traditional Foundations section. Articles for the Advances section are of particularly high value and impact. They receive expedited treatment and may be highlighted by an accompanying scientific commentary article and a press release. Further details are given in the November 2013 Editorial. The central themes of the journal are, on the one hand, experimental and theoretical studies of the properties and arrangements of atoms, ions and molecules in condensed matter, periodic, quasiperiodic or amorphous, ideal or real, and, on the other, the theoretical and experimental aspects of the various methods to determine these properties and arrangements.