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引用次数: 0
摘要
三维电子衍射(3D-ED)是一种功能强大的晶体学表征技术,可用于表征因晶体太小而无法进行 X 射线衍射的纳米级晶体。然而,为了精确地完善晶体结构,必须对布拉格衍射强度进行动态处理。布洛赫波模拟通常用于三维电子衍射,但由于衍射光束数量庞大,对于大单元晶体来说,计算成本会很高。本文提出了一种替代方法,即 "散射簇算法"(SCA),用更简单的矩阵乘法取代布洛赫波中的特征分解操作。SCA 的基本原理是,给定布拉格反射的强度主要由相邻衍射光束簇的强度传递(即 "散射")决定。然而,使用矩阵乘法的代价是必须将样品分成一系列薄片,并对衍射光束进行迭代计算,这与多片方法类似。因此,SCA 更适用于薄样品。我们在三异丙基硅烷(TIPS)五碳烯和红芘这两种具有大单元的有机材料上演示了 SCA 的准确性和速度。
Modelling dynamical 3D electron diffraction intensities. I. A scattering cluster algorithm.
Three-dimensional electron diffraction (3D-ED) is a powerful technique for crystallographic characterization of nanometre-sized crystals that are too small for X-ray diffraction. For accurate crystal structure refinement, however, it is important that the Bragg diffracted intensities are treated dynamically. Bloch wave simulations are often used in 3D-ED, but can be computationally expensive for large unit cell crystals due to the large number of diffracted beams. Proposed here is an alternative method, the `scattering cluster algorithm' (SCA), that replaces the eigen-decomposition operation in Bloch waves with a simpler matrix multiplication. The underlying principle of SCA is that the intensity of a given Bragg reflection is largely determined by intensity transfer (i.e. `scattering') from a cluster of neighbouring diffracted beams. However, the penalty for using matrix multiplication is that the sample must be divided into a series of thin slices and the diffracted beams calculated iteratively, similar to the multislice approach. Therefore, SCA is more suitable for thin specimens. The accuracy and speed of SCA are demonstrated on tri-isopropyl silane (TIPS) pentacene and rubrene, two exemplar organic materials with large unit cells.
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.
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