Abstract
Single-crystal electron diffraction (SCED) is emerging as an effective technique to determine and refine the structures of unknown nano-sized crystals. In this work, the implementation of the continuous rotation electron diffraction (cRED) method for high-throughput data collection is described. This is achieved through dedicated software that controls the transmission electron microscope and the camera. Crystal tracking can be performed by defocusing every nth diffraction pattern while the crystal rotates, which addresses the problem of the crystal moving out of view of the selected area aperture during rotation. This has greatly increased the number of successful experiments with larger rotation ranges and turned cRED data collection into a high-throughput method. The experimental parameters are logged, and input files for data processing software are written automatically. This reduces the risk of human error, and makes data collection more reproducible and accessible for novice and irregular users. In addition, it is demonstrated how data from the recently developed serial electron diffraction technique can be used to supplement the cRED data collection by automatic screening for suitable crystals using a deep convolutional neural network that can identify promising crystals through the corresponding diffraction data. The screening routine and cRED data collection are demonstrated using a sample of the zeolite mordenite, and the quality of the cRED data is assessed on the basis of the refined crystal structure.
Highlights
Several techniques have been developed for collecting single-crystal electron diffraction data (SCED) by rotating the crystal in the electron beam
We describe the practical implementation of the continuous rotation electron diffraction (cRED) data collection routine in Instamatic and the application of SerialED data in combination with machine learning for crystal screening
We have developed an object-oriented wrapper around the TEMCOM application programming interface (API) for control of the JEOL microscope, which was inspired in part by the PyScope library (Suloway et al, 2005)
Summary
Several techniques have been developed for collecting single-crystal electron diffraction data (SCED) by rotating the crystal in the electron beam. The number of steps required to collect data is greatly reduced, crystal tracking during continuous crystal rotation can be achieved by defocusing the diffraction pattern at regular intervals, and experimental log files and instruction files for data processing software are written automatically. This makes the cRED method more accessible to novice or irregular users, and minimizes the risk of human error, which in turn leads to more reproducible experiments and enables highthroughput data collection. The software is developed for Windows, because it needs to access the microscope API
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