Students write and defend a proposal for experimental investigation of a research problem not directly related to their thesis topic. Project selected requires approval of thesis committee, and involves primarily library research. Credit, 1.

Not available at this time

Review of classical and statistical ther-modynamics, configuration and conformation of isolated polymer chains, the rotational isomeric state model, thermody-namics and statistical mechanics of polymer solutions, scaling theory, single chain dynamics, scattering (light, x-ray, neutron). Karasz, Muthukumar, Russell, Strey

Polymer structure, classification of polymerization reactions, theory and practice of step growth polymerization, radical polymerization, ionic polymerization, ring-opening polymerization, polymerization by transition metal catalysts. McCarthy, Penelle

Physical and mathematical principles required to understand and solve engineering problems encountered with polymeric materials. Vectors and tensor operations, stress-strain analysis in solids, fluid mechanics, transport equations for mass and energy, nonlinear physical properties, overview of polymer processing. Hoagland, Lesser

Preparation and characterization of the most important types of polymer types. Radical, cationic, anionic polymerization, copolymerization, Ziegler-Natta polymerization, step growth polymerization; suspension and emulsion polymerization; group transfer polymerization; metathesis polymerization. McCarthy

Characterization of polymers by up to fifteen methods, including spectroscopic (nuclear magnetic resonance, Raman, infrared), mechanical (tensile, dynamic mechanical, rheological), microscopic (electron microscopy), physiochemical (intrinsic viscosity, differential scanning, calorimetry, gel permeation chromatography) and scattering (light, x-rays). Molecular simulation techniques introduced. Lectures provide state-of-the-art description of these and additional polymer characterization methods. Gido, Hsu, Russell

Characterization of polymers by up to fifteen methods, including spectroscopic (nuclear magnetic resonance, Raman, infrared), mechanical (tensile, dynamic mechanical, rheological), microscopic (electron microscopy), physiochemical (intrinsic viscosity, differential scanning, calorimetry, gel permeation chromatography) and scattering (light, x-rays). Molecular simulation techniques introduced. Lectures provide state-of-the-art description of these and additional polymer characterization methods. Gido, Hsu, Russell