Structural damage reduction in protected gold clusters by electron diffraction methods

IF 3.56 Q1 Medicine
Eduardo Ortega, Arturo Ponce, Ulises Santiago, Diego Alducin, Alfredo Benitez-Lara, Germán Plascencia-Villa, Miguel José-Yacamán
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引用次数: 4

Abstract

The present work explores electron diffraction methods for studying the structure of metallic clusters stabilized with thiol groups, which are susceptible to structural damage caused by electron beam irradiation. There is a compromise between the electron dose used and the size of the clusters since they have small interaction volume with electrons and as a consequence weak reflections in the diffraction patterns. The common approach of recording individual clusters using nanobeam diffraction has the problem of an increased current density. Dosage can be reduced with the use of a smaller condenser aperture and a higher condenser lens excitation, but even with those set ups collection times tend to be high. For that reason, the methods reported herein collects in a faster way diffraction patterns through the scanning across the clusters under nanobeam diffraction mode. In this way, we are able to collect a map of diffraction patterns, in areas with dispersed clusters, with short exposure times (milliseconds) using a high sensitive CMOS camera. When these maps are compared with their theoretical counterparts, oscillations of the clusters can be observed. The stability of the patterns acquired demonstrates that our methods provide a systematic and precise way to unveil the structure of atomic clusters without extensive detrimental damage of their crystallinity.

Abstract Image

用电子衍射方法降低受保护金团簇的结构损伤
本文利用电子衍射方法研究了易受电子束辐照破坏的巯基稳定金属团簇的结构。在使用的电子剂量和团簇的大小之间有一个折衷,因为它们与电子的相互作用体积小,因此在衍射图样中反射较弱。使用纳米束衍射记录单个簇的常用方法存在电流密度增加的问题。用量可以减少与使用较小的聚光镜孔径和较高的聚光镜激发,但即使这些设置收集时间往往是高的。因此,本文报道的方法在纳米束衍射模式下通过扫描团簇以更快的方式收集衍射图案。通过这种方式,我们能够使用高灵敏度CMOS相机在短曝光时间(毫秒)内收集分散簇区域的衍射图案图。当这些图与理论对应图相比较时,可以观察到星团的振荡。所获得的模式的稳定性表明,我们的方法提供了一种系统和精确的方法来揭示原子团簇的结构,而不会对其结晶度造成广泛的有害损害。
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
Advanced Structural and Chemical Imaging
Advanced Structural and Chemical Imaging Medicine-Radiology, Nuclear Medicine and Imaging
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