Chemistry-Study and teaching; Handouts; Homework; Problem solving; Chemical bonds; Quantum theory; Molecular orbitals; Molecules-Models
Three multi-part questions with the goal of applying the theory of quantum mechanics and methods of molecular modeling to a diatomic molecule and the polyatomic molecule. It deals with molecular orbital theory and chemical bonding.
Chemistry-Study and teaching; Handouts; Valence (Theoretical chemistry); Chemical bonds; Electrons; Molecular orbitals
In class, we have used the Valence Bond (VB) approach to understand chemical
bonding. At the qualitative level, VB is relatively easy to use and does not require a deep
knowledge of quantum mechanics and group theory. The electron-dot formalism of...
Chemistry-Study and teaching; Homework; Molecular orbitals; Chemical bonds
Introduction: In class we applied molecular orbital theory to a few simple examples with the goal of understanding the nature of the chemical bond. The qualitative approach is complemented by numerical calculations and the interpretation of these...
Chemistry-Study and teaching; Molecules-Models; Lewis dot structures; Molecular structure
Experiment designed to acquaint a student with selected but instructive techniques of molecular modeling. It involves using computational methods to answer chemical questions.
Chemistry-Study and teaching; Handouts; Quantum theory; Eigenfunctions; Perturbation (Quantum dynamics)
Handout on perturbation theory in quantum mechanics written by the instructor as a supplement to the textbook. It looks at an approach for the case where a problem differs slightly from one that can be solved exactly.
Chemistry-Study and teaching; Spectroscopy, Nuclear magnetic resonance;
Experiment designed to introduce the fundamental principles and practice of magnetic resonance imaging (MRI), a form of NMR spectroscopy, by obtaining and examining a two-dimensional image of the stem or bud from a plant.
Chemistry-Study and teaching; Chemistry, Physical and theoretical
Students are instructed to use the Unix version of Spartan that is installed on six SGI workstations in the Computational
Biology teaching laboratory to complete these five modeling excercises. Additional resources are included.
Chemistry-Study and teaching; Handouts; Stoichiometry; Chemical equilibrium
Introduction. In class we observed that no reaction goes to completion and have discussed qualitatively the consequences of this insight. It is also possible to deal quantitatively with chemical equilibria. The chemist's approach should start with...
Chemistry-Study and teaching; Handouts; Stoichiometry; Chemical equilibrium
Introduction. Part II of the handout will apply the approach introduced in Part I to acid-base chemistry. We shall focus on two cases where the application of stoichiometry leads to great simplifications: strong acids which are essentially 100%...
Chemistry-Study and teaching; Chemical bonds; Transition metals; Molecular orbitals
Introduction. The purpose of this handout is to provide a simple model for the bonding in transition-metal complexes as a framework for understanding and interpreting the most important properties of these complexes. We shall deal mostly with the...
