Electron diffraction methods have emerged as powerful tools for elucidating the atomic structures of a wide range of materials. Among these methods, cryo‐electron microscopy and microcrystal electron ...

Recent advances in electron microscopy and diffraction have increasingly focused on capturing dynamical processes at unprecedented temporal resolutions. Ultrafast electron microscopy and diffraction ...

Last November, Quantum Design and NanoMEGAS invited industry and research professionals to learn more about the theoretical and practical applications of Precession Electron Diffraction (PED).

With the demand for high-performnce materials increasing, it has become necessary to optimize their structural properties at the nanoscale, underscoring the importance of systematic and routine ...

A new research study from Opto-Electronic Advances discusses tailoring electron vortex beams with customizable intensity patterns by electron diffraction holography. In a first demonstration of ...

The UK’s first dedicated electron diffraction center is due to open in the Summer of 2023. The new facility will help UK nanoscientists to characterize the "tiniest of crystals", according to Derek ...

Could you start by explaining your background in crystallography and how you began using the Rigaku Synergy-ED system? Fraser: I began my journey into crystallography at the University of Edinburgh in ...

(Nanowerk News) Metal-Organic Frameworks (MOFs) are porous crystalline materials whose structure resembles a scaffold of beams around a large empty space; this internal space can be used to store ...

Electron-beam inspection is proving to be indispensable for finding critical defects at sub-5nm dimensions. The challenge now is how to speed up the process to make it economically palatable to fabs.

This publication has been developed based on the results of the Technical Meeting on Advances in Post-Irradiation Examination Techniques for Power-Reactor Irradiated Fuels and Innovative Fuels held in ...

National University of Singapore (NUS) physicists have developed a computational imaging technique to extract three-dimensional (3D) information from a single two-dimensional (2D) electron micrograph.