AP Seminar - Frontiers in Glassy Materials: Spatial and Temporal Complexity at the Nanoscale

Much of our day to day lives is spent interacting with some form of glassy material: looking through a silicate glass windshield while driving, drinking from a polycarbonate glass bottle, or watching a display powered by organic glass light emitting diodes. However, the ubiquity and apparent featurelessness of glasses masks deep complexity associated with structural disorder, cooperative, spatially non-uniform atomic motions, and metastable thermodynamics. This talk will provide an introduction to the thermodynamics, kinetics, and structures common to the glassy state of materials, and then present highlights of recent glass research at the University of Wisconsin-Madison. These highlights include: (1) Surface diffusion on glasses that can be 10⁸ times faster than bulk diffusion at the same temperature. (2) Use of surface to grow glass thin films more stable than natural ambers aged for thousands of years and glasses with quenched-in liquid-crystal order. (3) The first real-space images of nanometer-scale spatially heterogeneous dynamics near the glass transition temperature. (4) Non-classical, two-step nucleation of crystals from a metallic glass-forming melt at large undercooling. Many of these advances are made possible by advanced instrumentation for time-resolved electron nanodiffraction and four-dimensional scanning transmission electron microscopy.