Harden M. McConnell Lecture
About the Lecture
Thermodynamics provides a robust conceptual framework and set of laws that govern the exchange of energy and matter. Although these laws were originally articulated for macroscopic objects, nanoscale systems also exhibit "thermodynamic-like" behavior – for instance, biomolecular motors convert chemical fuel into mechanical work, and single molecules exhibit hysteresis when manipulated using optical tweezers. To what extent can the laws of thermodynamics be scaled down to apply to individual microscopic systems, and what new features emerge at the nanoscale? I will describe some of the challenges and recent progress – both theoretical and experimental – associated with addressing these questions. Along the way, my talk will touch on non-equilibrium fluctuations, "violations" of the second law, the thermodynamic arrow of time, nanoscale feedback control, strong system-environment coupling, and quantum thermodynamics.
About the Speaker
Christopher Jarzynski received his AB degree from Princeton University (1987) and his PhD from the University of California, Berkeley (1994), both in Physics. After a postdoctoral fellowship at the Institute for Nuclear Theory in Seattle, he spent ten years in the Theoretical Division at Los Alamos National Laboratory, first as a postdoc and then as a technical staff member. In 2006 he moved to the University of Maryland, College Park. He is a Distinguished University Professor with appointments in the Department of Chemistry and Biochemistry, the Institute for Physical Science and Technology, and the Department of Physics.
Jarzynski's research interests include theoretical and computational work at the interface of physics, chemistry and biology, with a particular focus on nonequilibrium phenomena and the application of thermodynamic principles to microscopic systems. In 1996 he derived an equality that relates irreversible work to equilibrium free energy differences, which has been verified in numerous experiments over the past two decades. His recent research focus includes quantum control and thermodynamics, the thermodynamic arrow of time, and the physical implications of information processing. His has received the Sackler Prize in the Physical Sciences (2005), the Lars Onsager Prize in theoretical statistical physics (2019), and a Guggenheim Fellowship (2020), among other awards. He is a Fellow of the American Physical Society and an elected member of the American Academy of Arts and Sciences and the US National Academy of Sciences.
Faculty Host: Daniel Weitekamp, Professor of Chemical Physics