Student Hosted Colloquium: Professor Sharon Glotzer, University of Michigan
About the Seminar
Entropic Bonding in Colloidal Crystals
A central paradigm of science, chemical bonding permits atoms to form everything from molecules and compounds to crystals and living matter. Remarkably, nanoparticles can self-assemble into the same crystal structures as atoms – even quasicrystals, clathrate structures and crystals with large unit cells, and even when only entropic forces are present. In crowded colloidal systems of hard particles, emergent, directional, and effectively attractive entropic forces create valency that leads to long-range order, as well as twinning, fluid-fluid phase transitions, and other phenomena occurring in atomic and molecular systems. In this talk, we discuss these interesting parallels and describe attempts to develop a theory to predict entropically stable colloidal crystal structures from nanoparticle shape that has parallels with Kohn-Sham density functional theory.
About the Speaker
Sharon C. Glotzer is the John W. Cahn Distinguished University Professor of Engineering and the Stuart W. Churchill Collegiate Professor of Chemical Engineering and Professor of Materials Science and Engineering at the University of Michigan, Ann Arbor. She also holds faculty appointments in Physics, Applied Physics, and Macromolecular Science and Engineering. Since July 2017, she has served as the Anthony C. Lembke Department Chair of Chemical Engineering at the University of Michigan.
Her research on computational assembly science and engineering aims toward the predictive materials design of colloidal and soft matter. Using computation, geometrical concepts, and statistical mechanics, her research group seeks to understand the complex behavior emerging from simple rules and forces and to use that knowledge to design new materials. Glotzer’s group also develops and disseminates powerful open-source software, including the particle simulation toolkit HOOMD-blue, which allows for fast molecular simulation of materials on graphics processors, the signac framework for data and workflow management, and freud for analysis and visualization. (Link to Glotzer Lab page.)
Glotzer received her Bachelor of Science degree in Physics from UCLA and her PhD in Physics from Boston University. She is a member of the National Academy of Sciences, the National Academy of Engineering, and the American Academy of Arts and Sciences. She is a Fellow of the American Association for the Advancement of Science, the American Institute of Chemical Engineers, the American Physical Society, the Materials Research Society, and the Royal Society of Chemistry.
Glotzer is the recipient of numerous awards and honors, including most recently the 2025 Irving Langmuir Award in Chemical Physics from the American Physical Society, the 2025 Peter Debye Award in Physical Chemistry from the American Chemical Society, the 2024 David Turnbull Lectureship Award from the Materials Research Society, and the 2024 Foundations of Molecular Modeling and Simulation (FOMMS) Medal for her fundamental contributions to the development of computational methods of particle assembly. In 2023, Glotzer was honored to be named a Clarivate Citation Laureate, joining a cohort of 23 world-class researchers who have made significant contributions across a diverse range of fields. Other awards include the Aneesur Rahman Prize for Computational Physics from the American Physical Society in 2019, the 2016 Alpha Chi Sigma Award from the American Institute of Chemical Engineers, and the 2014 MRS Medal from the Materials Research Society.