Polymers are ubiquitous in modern life, as are complex fluids – soft materials with properties between those of liquids and solids. Researchers in the Chemical Engineering Department are developing polymer films for use in energy conversion, new polymers for flexible solar cells, membranes and medical devices, and polymer coatings that change properties when exposed to stimuli. The research in this area includes rheology studies, molecular simulation, colloid self-assembly, gelation and percolation.
Ongoing research topics for Professor Scott Fogler and his research group include: flow, reaction, precipitation and modeling of wax deposition in subsea pipelines, asphaltene deposition and precipitation, rheometric and microscopic studies of crystallization and of gel breaking phenomena, asphaltene characterization and precipitation kinetics, and catalyzed dissolution of minerals. A number of research results are now being used in industrial applications.
Professor Jinsang Kim and his research group develop design principles for self-organizing polymers and approaches for engineering the band gap of semiconducting polymers. The group also studies phosphorescent organic crystals, biosensors, flexible solar cells and bio-inspired conductive adhesives.
Professor Joerg Lahann’s research interest is focused on the development of active, multi-functional bio-interfaces, which are applicable to a range of biomedical applications. His group’s recent advances in the molecular design of active nanostructures include the introduction of reactive coatings, reversibly switching surfaces and anisotropic nanoparticles that support the vision of smart interfaces and act as templates in time-controlled surface interactions.
Professor Ronald Larson and his group study polymer rheology through experiment, theory and simulation. The team is also developing colloidal materials that self assemble and can be reconfigured on command or in response to environmental signals to form novel optical and electronic materials. Using molecular dynamics methods, the Larson Group also simulates surfactant structures and properties.
With his research group, Professor Timothy Scott is developing ways to use free radicals to make new kinds of polymers, which may be useful for medical devices or energy capture and storage.
Professor Michael Solomon and his research group investigate complex fluids—soft materials with properties intermediate between fluids and solids. Solomon’s current interests include nanocolloidal assembly, colloidal gelation, and the biomechanics of bacterial biofilms. Applications that interest the group include creating new optical materials, sensors, biomedical devices and procedures, as well as materials for energy management.
Professor Peter Tessier and his group aim to develop next generation technologies for designing, discovering, engineering, characterizing, formulating and delivering monoclonal antibodies and other biologics for molecular imaging, diagnostic and therapeutic applications. Their research in the area of complex fluids involves the use of experimental and computational approaches for understanding molecular determinants of protein solution properties (solubility, viscosity, aggregation) and other key protein properties (stability, specificity and affinity). With an eye toward applications, the Tessier lab also develops novel high-throughput screening tools for discovering new biologics and identifying rare variants with drug-like properties for therapeutic applications.
Professor Anish Tuteja and his group use polymers to address key challenges in the areas of renewable energy and environmental science. They develop super oil-repellent surfaces, super water-repellent surfaces, ice-repellent surfaces, membranes and polymer nanocomposites. Applications include the separation of oil and water and energy-conversion materials for solar cells.
Professor Robert Ziff and his colleagues use computer simulation and mathematical modeling to study a variety of problems of interest to fields of chemical engineering, mathematics, and physics. The percolation model is used to study such phenomena as flow through porous media, conductivity of composites such as nano-tubules, polymer gelation and growth of the giant component in networked systems. We have developed several numerical algorithms to obtain precise critical connectivity thresholds for two and three-dimensional systems, and have identified several universal properties of the critical percolation “fractal.”