This course covers fundamentals of central topics in inorganic chemistry from historical to modern-day perspectives. Topics include: coordination compounds (history, structure, bonding theories, reactivity, applications); solid state chemistry (crystals, lattices, radius ratio rule, defect structures, silicates & other minerals); and descriptive chemistry of the elements.
This lecture course will introduce students to the interdependence of chemical bonding, spectroscopic characteristics, and reactivity properties of coordination compounds and complexes using the fundamental concept of symmetry. After reviewing atomic structure, the chemical bond, and molecular structure, the principles of coordination chemistry will be introduced. A basic familiarity with symmetry will be formalized by an introduction to the elements of symmetry and group theory. The students will use symmetry and group theory approaches to understand central atom hybridization, ligand
Four pairs of students represent quadruple bonding in metal complexes by "forming bonds" with a variety of physical methods involving actions like facing each other while holding hands (sigma bond), touch hands and feet of their partner "above and below" the plane (two pi bonds), touching hands and feet while facing each other (delta bond). This results in a "Twister"-like pile of students resembling the quadruple bonding interaction
This course introduces the chemistry of transition metals and main group elements. Topics include theories of bonding, kinetics and mechanisms of reactions of transition metal complexes, oxidation-reduction reactions, hard-soft acid-base theory, and solid-state chemistry. Applications of inorganic chemistry to other areas (organic, analytical, and physical chemistry, as well as biology and biochemistry) are highlighted throughout the course. The laboratory portion of the course involves the synthesis and spectroscopic investigation of inorganic complexes.
An introduction to modern inorganic chemistry, including a description of transition- metal complexes and their role as catalysts, and a survey of the reactivity of selected elements of the main group. Three-hour lecture, three-hour laboratory
This is the fourth in a series of exercises used to teach computational chemistry. It has been adapted, with permission, from a Shodor CCCE exercise (http://www.computationalscience.org/ccce). It uses the WebMO interface for drawing structures and visualizing results. WebMO is a free web-based interface to computational chemistry packages (www.webmo.net).
Part 7 of the Flipped Learning in General Chemistry Series. This video introduces the concept of an oxidation state, which is a tool used to keep track of electrons in chemical reactions.
Part 6 of the Flipped Learning in General Chemistry Series. This video reviews the concept of the mole and shows how to use atomic masses of individual elements to calculate formula masses of covalent and ionic compounds. The video also introduces the concept of stoichiometry conversions.
Part 5 of the Flipped Learning in General Chemistry Series. This video introduces valence shell electron pair repulsion (VSEPR) theory and teaches students to predict the geometry of a molecule from its Lewis structure.