Field-Theoretic Simulations: From Advanced Materials to Quantum Liquids
Lecture by Glenn H. Fredrickson
Departments of Chemical Engineering and Materials
Materials Research Laboratory
University of California, Santa Barbara
Tuesday, April 24, 2018
Lecture at 4:00 PM
1610 Engineering Hall
Reception at 3:30 p.m. Cheney Room Engineering Hall
Field-theoretic representations of many-body problems in classical and quantum statistical mechanics have been known for more than 70 years, but have largely enabled approximate analytical calculations. Over the past decade, my group has shown that the complex-valued statistical field theory models of classical fluids can be directly tackled by numerical simulation. Such “field-theoretic simulations” (FTS) are advantaged over conventional particle-based computer simulations in a variety of situations, especially dense melts of high molecular weight polymers and systems with long-ranged interactions, such as polyelectrolytes. They are also well-suited for multi-scale simulations spanning nanometers to microns.
This talk will introduce the construction of field theory models of polymeric fluids and the FTS framework. Two application examples will be provided: the design of uniquely hard-tough-elastic thermoplastics, and the complexation behavior of oppositely charged polyelectrolytes. I will conclude by discussing a “coherent states” (CS) representation of interacting polymers that offers potential computational advantages. A structural similarity with bosonic quantum field theories suggests a powerful new FTS approach to probe superfluidity and other exotic collective phenomena in cold bosons.
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Glenn Fredrickson received B.S. and Ph.D. degrees in chemical engineering from the University of Florida and Stanford University, respectively. He was a member of technical staff at AT&T Bell Laboratories from 1984 to 1990 and has been on the faculties of Chemical Engineering and Materials at the University of California, Santa Barbara since that time. Glenn has advised a wide range of companies in the chemicals and materials sector and served as Chief Technology Officer of Mitsubishi Chemical Holdings Corporation during the period 2014-17. He has been honored by major research awards from the American Physical and Chemical Societies, the Materials Research Society, and the American Institute of Chemical Engineers, and was elected to the National Academy of Engineering and the American Academy of Arts and Sciences.