Lectures in course CH-450: Solid state chemistry and energy applications

Modeling Class: Vesta Software Visualization

Explores crystal structure visualization using Vesta software for CCP and HCP arrangements.

MOF Applications: Storage, Separation, Sensing

Explores MOF applications in storage, separation, and sensing, emphasizing their role in reducing energy input and capturing carbon dioxide.

Synthesis of Solid State Materials

Covers methods for synthesizing solid state compounds, including high temperature ceramic and hydrothermal methods, and the challenges of avoiding volatile reactants.

Solid State Chemistry: Fundamentals and Applications

Delves into the fundamentals and applications of solid state chemistry, covering classification, characterization techniques, and various practical uses.

Energy Storage Technologies: SMES, Superconductivity, and Lithium-Ion Batteries

Explores the significance of SMES systems, superconductivity, and lithium-ion batteries, highlighting their roles in energy storage and global sustainability.

Crystal Systems: Unit Cells and Symmetry

Explores crystal systems, unit cells, symmetry, and close-packed structures in solid state chemistry.

Biomass Conversion and Hydrogen Storage

Covers biomass conversion, hydrogen storage, catalyst properties, porous materials, metal hydrides, and DOE targets for hydrogen storage.

Crystal Symmetry and Structures

Explores crystal symmetry, systems, lattices, and space groups, emphasizing solid state structures and close-packed arrangements.

Crystal Structures: Miller Indices and Lattice Planes

Covers projected views, Miller indices, and lattice planes in crystal structures.

Synthesis of Solid State Compounds

Covers the synthesis of solid state compounds using high temperature methods and the importance of stoichiometric reactions and non-hygroscopic materials.

Characterization Approaches for Solid Materials

Covers fundamental characterization approaches for solid materials, focusing on elemental analysis, thermal analysis, microscopy, and neutron-based spectroscopies.

Solid State Materials Synthesis

Covers the synthesis of solid state compounds and the importance of stoichiometric reactions.

Neutrons vs X-rays

Compares neutrons and X-rays in diffraction analysis, focusing on their energy levels, interaction mechanisms, and penetrating capabilities.

Understanding Diffraction: X-rays vs Neutrons

Compares x-rays and neutrons for material structure analysis using diffraction patterns.

Characterization Techniques in Solid State Chemistry

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

Metal-Organic Frameworks: Structures, Properties, and Applications

Covers Metal-Organic Frameworks' unique properties, ligands, structures, and applications, including bipyridine-based MOFs and zeolitic imidazolate frameworks.

Thermal Analysis: Techniques and Applications

Explores thermal analysis techniques like TGA, DTA, and DFC, used for studying material properties and phase changes.

Thermal Analysis Techniques

Explores thermal analysis techniques like TGA, DTA, and DSC for material characterization.