This course introduces students to an in-depth study of the function and structural moiety of organic macromolecules of biological relevance. Topics to be discussed in this course will revolve around classification carbohydrates, stereoisomerism in carbohydrates, polyfunctional chemistry of simple sugars, cellulose and its derivatives, enzymatic glycogen hydrolysis, conversion of ATP to ADP, and proteins (classification, amino acids, peptides, determination of protein structure), nucleic acids, nucleosides, nucleotides, and synthetic polymers.

This course covers various aspects of spectroscopy particularly, electronic spectroscopy of atoms, ions and complex molecules, vibrational, rotational and laser spectroscopy, as well as, spectral interpretation and analysis of samples using molecular spectroscopic tools. Terms symbols for free atoms and ions, spectroscopic interpretation of colours of complexes, and elementary molecular orbital theory will be discussed. Broadly speaking, it provides a general overview of the concepts of absorption, emission, vibration, rotation, resonance and electron spin. Instrumental methods to be covered in this course will include UV-Vis spectroscopy, fluorescence, infrared spectroscopy, Raman spectroscopy, nuclear magnetic resonance, and mass spectrometry.

This course seeks to introduction students to the chemistry of the excited state and the consequences of absorption of light by molecules and extensions into the photochemistry of biological system. View in the perspective of a physical organic chemistry course, it will allow students to reasonably evaluate the reactivity of an excited state and to analyze its monomolecular fate (photophysics), as well as, its bimolecular interactions. It will also provide an understanding of principles underlying photochemical reactions such as photosynthesis, and an appreciation of light – initiated chemical processes, fluorescence, phosphorescence, and quantum yields and applications of photochemistry to organic systems.

This is a follow up course to CHE 201. Topics to be discussed will include: general properties of first and second row transition metals, and actinides and lanthanides series.

Application to catalysis especially for some industrial processes such as the Haber and Contact processes.