Douglas Stone
Yale University
Recently invented micro and nano lasers have challenged our understanding of lasers and revealed the absence of a predictive theory. Perhaps most surprising is the existence of random lasers, based on multiple scattering between nanoparticles in the presence of gain. While these lasers behave in most respects like conventional lasers, they have no mirrors or cavity of any kind. Further, the linear scattering spectrum reveals no long-lived resonances to support lasing. In the absence of such resonances, conventional semiclassical laser theory has no starting point. We have recently developed a modern formulation of semiclassical laser theory which elucidates the nature of lasing modes in cavities of arbitrary complexity and arbitrary leakiness, including the case of random lasers. The theory also treats the strong non-linear interaction between lasing modes to all orders, and has been shown to agree with full numerical solutions of the lasing equations with no adjustable parameters. We are thus in a position to understand qualitatively complex lasing systems (such as random, chaotic and self-similar lasing structures), and in the near future produce a truly predictive theory for many lasers of applied and fundamental interest.
Friday, February 27 at 4:00 PM
Room L211, Technological Institute
Refreshments are served at 3:30 PM
