Accelerator-based high-energy electron diffraction determines 3D atomic structure of materials New method using ultrashort ...

Materials called relaxor ferroelectrics have been used for decades in technologies like ultrasounds, microphones, and sonar ...

insights from industryDr. Stuart WrightSenior ScientistGatan/EDAX In this interview, Dr. Stuart Wright, a Senior Scientist at Gatan/EDAX, talks to AZoMaterials about the versatile applications of ...

What is Electron Backscatter Diffraction (EBSD)? Electron backscatter diffraction (EBSD), also known as backscatter Kikuchi diffraction (BKD), is a powerful characterization technique used to analyze ...

MIT researchers uncover a hidden 3D atomic structure in relaxor ferroelectrics using electron ptychography, resolving a ...

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

For the first time, researchers directly characterized the 3D atomic structure of a relaxor ferroelectric, a class of ...

In materials science, particularly in the study of glasses, the intermediate range order (IRO) is one of the most intriguing research areas owing to its significant influence over the physical ...

MIT-led researchers have, for the first time, directly mapped the 3D atomic and polar structure of relaxor ferroelectrics, materials critical to sensors and energy devices. Using multi-slice electron ...

TEM works by accelerating electrons, typically with energies between 80 and 300 kV, and directing them through a specimen thin enough for electron transmission. Because of their very short wavelength ...