Wave Localization and the Hidden Structure of Disorder
- Speaker
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Svitlana Mayboroda, Ph.D.McKnight Presidential Professor, University of Minnesota
Presidential Lectures are a series of free public colloquia spotlighting groundbreaking research across four themes: neuroscience and autism science, physics, biology, and mathematics and computer science. These curated, high-level scientific talks feature leading scientists and mathematicians and are designed to foster discussion and drive discovery within the New York City research community. We invite those interested in these topics to join us for this weekly lecture series.
At the forefront of modern technology, matter structured at the nanometer and atomic levels increasingly reveals its wavelike nature. In recent years, cutting-edge experiments with ultracold atoms pushed the limits of fundamental physics, created new states of matter and offered the possibility of controlling quantum entanglement, with major potential applications in cryptography and quantum computing. The electronic waves confined in quantum wells yielded high-efficiency light-emitting diodes, which are about to revolutionize the energetics of lighting. At these scales, even the slightest disorder or irregularity can trigger one of the most puzzling and ill-understood phenomena: wave localization.
But what is wave localization? In this Presidential Lecture, Svitlana Mayboroda will discuss how it is an astonishing ability of physical systems to maintain vibrations in a small portion of the original domain, preventing extended propagation. One should not, however, think solely in terms of mechanical vibrations. Light is a particular example of an electromagnetic wave, Wi-Fi signals are waves, sound is a pressure wave and, since the rise of quantum physics, even matter is perceived as waves. Whether wanted or unwanted, known or ignored, exploited or only sustained, the localization of these waves plays a paramount role in our everyday life and the science and technology of the future. Mayboroda will discuss the intricate nature of this phenomenon, the perplexing rules of confinement, the geometry perceived by the human eye, and the very different geometry that guides the propagation of waves or the formation of free boundaries.
About the Speaker
Mayboroda is a professor of mathematics at ETH Zurich, a McKnight Presidential Professor at the University of Minnesota, and the director of the Simons Collaboration on Localization of Waves. Her work lies at the interface between partial differential equations, analysis and geometric measure theory. Her discoveries have led to a wide range of applications in condensed matter physics, cold atom systems and the research and engineering of organic and nonorganic semiconductor materials and devices. She is a recipient of the U.S. Blavatnik National Award in Physical Sciences and Engineering, the Stein Prize for New Perspectives in Analysis and the AWM-Sadosky Prize in Analysis. She is a member of the European Academy of Sciences and the German Academy of Sciences. In 2018, she was an invited sectional speaker at the International Congress of Mathematicians.