Lecture

TEM Specimen Preparation Methods: Organic Materials

Related lectures (32)

Explores sample preparation techniques for TEM, such as cleaved wedge method and ultramicrotomy, highlighting their importance in obtaining high-quality samples.

Transmission Electron Microscopy: Advanced Techniques

Explores advanced techniques in transmission electron microscopy, focusing on phase contrast imaging and camera settings.

Electron Microscopy: TEM

Explores Transmission Electron Microscopy (TEM), covering diffraction patterns, image formation, and contrast mechanisms.

High Resolution TEM: Imaging and Contrast

Explores High Resolution TEM principles for atomic-level crystal imaging.

Transmission Electron Microscopy

Covers the principles and applications of Transmission Electron Microscopy, including imaging, diffraction, contrast mechanisms, and in situ techniques.

Electron microscopy: Biological sample preparation

Explores electron microscopy principles and techniques for imaging biological structures, including fixation, embedding, staining, and aldehyde action.

Focused Ion Beam: Principles and Applications

Explores the principles and applications of Focused Ion Beam technology, including ion-solid interactions, ion milling, and nanofabrication.

Radiation-Matter Interaction: Electron Microscopy Introduction

Covers the principles and techniques of electron microscopy, focusing on the interaction between radiation and matter.

Imaging modes in TEM

Explores imaging modes in TEM, covering electron-matter interactions, diffraction patterns, image formation, contrast principles, and detector configurations.

Electron Microscopy: In Situ

Explores electron microscopy in situ, including time-resolved techniques and environmental TEM applications.

Sample Preparation: Techniques and Methods

Discusses the importance of sample preparation in electron microscopy and various techniques involved.

Introduction and Interaction with Radiation-Matter

Introduces electron microscopy, covering practical organization, sample preparation, radiation-matter interaction, and detector mechanisms.

Dynamical Scattering: Bend Contours

Explains the dynamical scattering effect of bend contours in TEM images of crystalline samples.

Protein Fibrillar Aggregation

Explores cryo-EM techniques for studying protein aggregation in neurodegenerative diseases, focusing on a-synuclein.

Electron Microscopy: In Situ

Explores electron microscopy in situ, covering time-resolved techniques and environmental TEM applications for SOFC.

Dynamical Effects: Thickness Fringes

Delves into the dynamical scattering effect of thickness fringes in TEM images, covering equations, intensity plots, and weak beam imaging.

TEM Lenses: Condenser, Objective, and Projector

Explores the roles of condenser, objective, and projector lenses in a TEM.

STEM: Scanning Transmission Electron Microscopy

Explores the principles of Scanning Transmission Electron Microscopy (STEM) for analytical microscopy, covering TEM diffraction, detectors, and EDS analysis.

Microscopy in situ and TEM Q&A

Explores in situ electron microscopy applications, traction experiments, environmental effects, XRD, and EDS.

High-Resolution TEM Imaging: Phase Contrast and Simulations

Covers high-resolution transmission electron microscopy imaging techniques, focusing on phase contrast, simulations, and the impact of aberrations on image interpretation.