Learn about radiation damage in cryo-electron microscopy, its impact on structural data, and strategies to minimize its effects in electron cryo-EM imaging.
Discover the basics of cryo-EM, its methodologies, and its impact on structural biology, enabling near-atomic resolution imaging of biological structures.
Learn how single-particle cryo-EM revolutionizes structural biology, enabling high-resolution imaging of biomolecules in their native states.
Learn how cryo-electron microscopy (cryo-EM) reveals detailed structures of large, dynamic biological molecules, providing key insights into macromolecular interactions.
Discover the stages of the cryo-EM workflow and how JEOL's advanced technology enhances macromolecular imaging for groundbreaking structural biology research.
Learn about Transmission Electron Microscopy (TEM) — its principles, components, and diverse applications in materials science, life sciences, and nanotechnology.
Explore the differences and synergies between cryo-EM and X-ray crystallography, two revolutionary techniques advancing structural biology and molecular discovery.
Learn about the techniques used in lithium ion battery analysis, including SEM, TEM, EMAS, and XRF. Discover how JEOL USA instruments can enhance battery quality and performance.
Explore the power of transmission electron microscopy (TEM) in high-resolution imaging and analytical capabilities with JEOL's blog post.