光学
数值孔径
摄影术
物理
图像分辨率
分辨率(逻辑)
材料科学
电子
光圈(计算机存储器)
埃
阴极射线
衍射
化学
结晶学
量子力学
人工智能
计算机科学
声学
波长
作者
Yi Jiang,Zhen Chen,Yimo Han,Pratiti Deb,Hui Gao,Saien Xie,Prafull Purohit,Mark W. Täte,Jiwoong Park,Sol M. Grüner,Veit Elser,David A. Muller
出处
期刊:Nature
[Nature Portfolio]
日期:2018-07-01
卷期号:559 (7714): 343-349
被引量:609
标识
DOI:10.1038/s41586-018-0298-5
摘要
Aberration-corrected optics have made electron microscopy at atomic resolution a widespread and often essential tool for characterizing nanoscale structures. Image resolution has traditionally been improved by increasing the numerical aperture of the lens (α) and the beam energy, with the state-of-the-art at 300 kiloelectronvolts just entering the deep sub-angstrom (that is, less than 0.5 angstrom) regime. Two-dimensional (2D) materials are imaged at lower beam energies to avoid displacement damage from large momenta transfers, limiting spatial resolution to about 1 angstrom. Here, by combining an electron microscope pixel-array detector with the dynamic range necessary to record the complete distribution of transmitted electrons and full-field ptychography to recover phase information from the full phase space, we increase the spatial resolution well beyond the traditional numerical-aperture-limited resolution. At a beam energy of 80 kiloelectronvolts, our ptychographic reconstruction improves the image contrast of single-atom defects in MoS2 substantially, reaching an information limit close to 5α, which corresponds to an Abbe diffraction-limited resolution of 0.39 angstrom, at the electron dose and imaging conditions for which conventional imaging methods reach only 0.98 angstrom.
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