Catalyst Characterization II: X-ray Techniques and Synchrotron Radiation

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Explores powder diffraction patterns, covering peak positions, intensities, widths, shapes, and texture analysis.

Synchrotrons and X-ray Techniques

Explores Laue diffraction principles, applications, and modern techniques in materials science and time-resolved experiments.

Powder Diffraction: Techniques and Applications

Explores powder diffraction techniques, applications, and limitations in various scientific fields.

Surface X-ray Diffraction II

Explores synchrotrons, x-ray lasers, relaxations, reconstructions, and superstructure rods in surface x-ray diffraction techniques.

Synchrotrons and X-ray Techniques

Explores the rotation method in single-crystal diffraction and serial crystallography techniques for studying atomic vibrations and protein dynamics.

Electron Diffraction: Basics & Applications

Explores electron diffraction basics, including Bragg's law, reciprocal lattice, and applications like crystal phase discrimination.

Powder Diffraction Techniques

Explores synchrotrons, x-ray lasers, detectors, structure solving, charge flipping, radiation testing, ultrafast diffraction, and total scattering techniques.

TEM imaging with diffraction contrast

Covers the basics of electron diffraction, diffraction theory, image formation, and X-ray diffraction techniques.

Diffraction Basics IV: Bragg's Law and Rotations

Explains Bragg's law, rotations in space, and the Ewald sphere for diffraction.

Glass Transition: Polymer Properties

Explores glass and melting transitions in polymers, including characterization methods and specific polymer properties.

Inelastic Scattering in Transmission Electron Microscopy

Introduces inelastic scattering in transmission electron microscopy, focusing on electron energy-loss spectroscopy principles and applications.

Characterization Techniques in Solid State Chemistry

Explores standard characterization techniques, focusing on x-ray diffraction and its importance in determining crystal structures.

X-rays: From Discovery to Applications

Explores the historical perspective, properties, and applications of X-rays, including diffraction, atomic resolution, and spectral colors of elements.

Crystal Structures: Determination and Analysis

Covers the determination and analysis of crystal structures using techniques such as X-ray diffraction and electron microscopy.

Crystallography: Atomic Bonding, Structures, and Diffraction

Covers crystallography, atomic bonding, structures, diffraction, and coordination numbers in materials.

Macromolecular Crystallography: Techniques and Applications

Explores macromolecular crystallography techniques using synchrotrons and x-ray lasers for large molecules.

Electron Diffraction: Basics & Applications

Covers the basics of electron diffraction, explaining contrast in TEM images and its applications in material analysis.

Monochromators: General Features

Introduces monochromators and their importance in selecting specific frequencies for experiments.

Synchrotrons and X-ray Techniques

Covers crystal diffraction basics, unit cells, lattice constants, and Miller indices.

Crystal Diffraction: Phases and Structure Factor

Explores crystal diffraction techniques, phases of scattered waves, and the structure factor.

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