Lecture

Chemical Analysis: X-Ray Micro-Analysis XRMA

Related lectures (32)

Analytical Electron Microscopy: Spectroscopy and Microanalysis

Explores Analytical Electron Microscopy techniques for chemical analysis using EELS and EDX.

Explores beam-matter interactions, thermal effects, chemical effects, atomic displacements, and matter emission mechanisms in electron microscopy.

Beam-Matter Interactions: Emission Phenomena

Explores beam-matter interactions, focusing on emission phenomena from core electron ionization by X-Rays and electrons, and the competition between Auger and X-Rays emissions.

Chemical analysis: X-Ray photoelectron spectrometry

Covers X-Ray Photoelectron Spectrometry (XPS), a surface analysis technique developed by Kai Siegbahn, explaining its components, mechanism, and analysis methods.

Scanning Electron Microscopy: Fundamentals and Applications

Covers the fundamentals of scanning electron microscopy, including electron matter interaction, imaging techniques, and related advanced topics.

Microstructure Characterization by SEM

Explores Microstructure Characterization by Scanning Electron Microscopy, covering interactions, morphology study, EDX analysis, and phase distribution.

Electron Microscopy Components

Covers electron microscope components, vacuum systems, aberrations, detectors, and specimen holders.

Electron Microscopy: EDS and ESEM

Explores EDS and ESEM principles, x-ray detection, ionization efficiency, Moseley's law, and ESEM sample environments.

Introduction to TEM

Introduces the basics of transmission electron microscopy, covering electron diffraction, imaging modes, specimen preparation, electron properties, and high-resolution imaging.

STEM and EDX

Covers STEM and EDX principles, X-ray generation, quantification methods, and analytical TEM applications.

Radiation-Matter Interaction: Electron Microscopy Introduction

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

Scanning Electron Microscopy

Explores Scanning Electron Microscopy principles, signal contrasts, resolution factors, and sample interactions.

Energy Dispersive X-ray Microanalysis

Covers Energy Dispersive X-ray Microanalysis, explaining how X-rays reveal elemental composition and discussing X-ray generation, detection, efficiency, and quantification.

Introduction and Interaction with Radiation-Matter

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

Electron Microscopy: TEM

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

Electron Microscopy: EDS

Explores Energy-Dispersive X-ray Spectroscopy (EDS) in electron microscopy, covering x-ray generation, detection, quantification, and mapping of elements in samples.

Energy Dispersive X-ray Microanalysis

Covers Energy Dispersive X-ray Microanalysis, exploring X-ray generation, detection, quantification, and challenges in accurate elemental analysis.

Scanning Electron Microscopy: Signals and Detectors

Covers the principles of Scanning Electron Microscopy, including SEM signals, detectors, and energy spectrum of electrons, as well as the efficiency of X-ray generation.

STEM: Scanning Transmission Electron Microscopy

Explores Scanning Transmission Electron Microscopy (STEM) principles, detectors, contrast mechanisms, and applications in high-resolution imaging.

SEM Basics: Introduction to Electron Microscopy

Introduces the basics of scanning electron microscopy, covering electron sources, lenses, vacuum system, and detectors.