从衍射数据中确定无序材料的结构。

Structure determination of disordered materials from diffraction data.

机构信息

Department of Earth Sciences, Cambridge University, Downing Street, Cambridge CB2 3EQ, United Kingdom.

出版信息

Phys Rev Lett. 2010 Mar 26;104(12):125501. doi: 10.1103/PhysRevLett.104.125501. Epub 2010 Mar 22.

DOI:10.1103/PhysRevLett.104.125501

PMID:20366543

Abstract

We show that the information gained in spectroscopic experiments regarding the number and distribution of atomic environments can be used as a valuable constraint in the refinement of the atomic-scale structures of nanostructured or amorphous materials from pair distribution function (PDF) data. We illustrate the effectiveness of this approach for three paradigmatic disordered systems: molecular C60, a-Si, and a-SiO2. Much improved atomistic models are attained in each case without any a priori assumptions regarding coordination number or local geometry. We propose that this approach may form the basis for a generalized methodology for structure "solution" from PDF data applicable to network, nanostructured and molecular systems alike.

摘要

我们表明，光谱实验中获得的关于原子环境数量和分布的信息可以作为从配对分布函数 (PDF) 数据精修纳米结构或非晶材料原子尺度结构的有价值的约束。我们通过三个典型的无序系统：分子 C60、非晶硅和非晶二氧化硅来说明这种方法的有效性。在每种情况下，都无需关于配位数或局部几何形状的任何先验假设，就可以获得改进得多的原子模型。我们提出，这种方法可能成为从 PDF 数据中进行结构“解析”的通用方法的基础，适用于网络、纳米结构和分子系统。

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从衍射数据中确定无序材料的结构。

Structure determination of disordered materials from diffraction data.

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