3D Nanocrystallography and the Imperfect Molecular Lattice.

IF 11.7 1区化学 Q1 CHEMISTRY, PHYSICAL Annual review of physical chemistry Pub Date : 2024-06-01 DOI:10.1146/annurev-physchem-083122-105226

Niko Vlahakis, James Holton, Nicholas K Sauter, Peter Ercius, Aaron S Brewster, Jose A Rodriguez

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Abstract

Crystallographic analysis relies on the scattering of quanta from arrays of atoms that populate a repeating lattice. While large crystals built of lattices that appear ideal are sought after by crystallographers, imperfections are the norm for molecular crystals. Additionally, advanced X-ray and electron diffraction techniques, used for crystallography, have opened the possibility of interrogating micro- and nanoscale crystals, with edges only millions or even thousands of molecules long. These crystals exist in a size regime that approximates the lower bounds for traditional models of crystal nonuniformity and imperfection. Accordingly, data generated by diffraction from both X-rays and electrons show increased complexity and are more challenging to conventionally model. New approaches in serial crystallography and spatially resolved electron diffraction mapping are changing this paradigm by better accounting for variability within and between crystals. The intersection of these methods presents an opportunity for a more comprehensive understanding of the structure and properties of nanocrystalline materials.

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三维纳米晶体学与不完美分子晶格。

晶体学分析依赖于原子阵列对量子的散射，这些原子阵列构成了一个重复的晶格。晶体学家们追求的是由理想晶格构成的大晶体，而对于分子晶体来说，不完美是常态。此外，用于晶体学研究的先进 X 射线和电子衍射技术为研究边缘只有数百万甚至数千个分子长的微米级和纳米级晶体提供了可能。这些晶体的大小接近传统晶体不均匀和不完美模型的下限。因此，X 射线和电子衍射产生的数据显示出更高的复杂性，对传统模型的挑战更大。序列晶体学和空间分辨电子衍射绘图的新方法正在改变这种模式，因为它们能更好地考虑晶体内部和晶体之间的可变性。这些方法的交叉使用为更全面地了解纳米晶体材料的结构和特性提供了机会。

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来源期刊

Annual review of physical chemistry 化学-物理化学

CiteScore

28.00

自引率

0.00%

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期刊介绍： The Annual Review of Physical Chemistry has been published since 1950 and is a comprehensive resource for significant advancements in the field. It encompasses various sub-disciplines such as biophysical chemistry, chemical kinetics, colloids, electrochemistry, geochemistry and cosmochemistry, chemistry of the atmosphere and climate, laser chemistry and ultrafast processes, the liquid state, magnetic resonance, physical organic chemistry, polymers and macromolecules, and others.

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