Stephen Kevan


Stephen Douglas Kevan is an American condensed matter physicist who researches "surface and thin film physics; electronic structure and collective excitations at surfaces; nanoscale spatial and temporal fluctuations in magnetic and other complex materials". He is the current director of the Advanced Light Source at Lawrence Berkeley National Laboratory in Berkeley, California. He is also a faculty member on leave from the University of Oregon and served as division deputy for science at the ALS prior to his directorship.

Education

Kevan graduated Summa cum Laude from Wesleyan University in 1976 with a B.A. in chemistry. In 1980 he earned a Ph.D. in physical chemistry from the University of California, Berkeley, working with David Shirley, with a dissertation entitled Normal Emission Photoelectron Diffraction: a New Technique for Determining Surface Structure.

Career

Kevan worked at Bell Laboratories as a member of technical staff from 1980-1986. In 1986 he joined the faculty at the University of Oregon as an associate professor of physics; since 1991 he has held a full professorship. From 2007 to 2012, he was Physics Department Head and was also Director of the University of Oregon Materials Science Institute. On leave from UO, Kevan currently serves as Deputy Division Director for Science at the Advanced Light Source at Lawrence Berkeley National Laboratory. He has also served as Associate Editor and North American Regional Editor of the New Journal of Physics.
Kevan's 30-year research career has focused on assuring the health and vitality of synchrotron light sources in the United States and abroad. He has contributed to condensed matter physics and physical chemistry through understanding how microscopic interactions and fluctuations produce novel material properties, particularly in the context of surface and thin film physics and exotic magnetism. His early Fermiology studies using photoemission verified experimentally the Fermi surface nesting mechanism for the spin density wave ground state of chromium and also contributed to understanding electronic instabilities in charge density wave materials and surface reconstructions. He also characterized the role of non-adiabatic damping of adsorbate vibrations and the spin-splitting of surface bands by the Rashba effect.
More recently he has probed the microscopic-macroscopic connection, developing tools to study microscopic magnetic fluctuations using coherent soft x-ray beams. His current emphasis is to probe, on the scale of a few domains, intermittent dynamics and memory effects in field- and thermally driven magnetization reversal. Understanding the impact of newly discovered hidden symmetries on these cascades is important to understanding microscopic intermittency in a much broader context.

Honors