Abstract :
Summary form only given. High-Q photonic-crystal nanocavities are currently the focus of much interest because they can strongly confine photons in a tiny space. Nanocavities with ultra-high quality (Q) factors exceeding 2,000,000 and modal volumes of a cubic wavelength have been successfully realized. If the Q factor could be dynamically controlled within the lifetime of a photon, significant advances would be expected in areas of physics and engineering such as the slowing and/or stopping of light and quantum information processing. For these applications, the transfer, storage, and exchange of photons in nanocavity systems on such a time-scale are highly desirable. In the present talk, I will at first describe the recent progress of ultra-high-Q nanocavities from the experimental and theoretical points of views. Then, I will present the demonstration of dynamic control of the Q factor, by constructing a system composed of a nanocavity, a waveguide with nonlinear optical response, and a photonic-crystal hetero-interface mirror. The Q factor of the nanocavity is successfully changed from ~3,800 to ~22,000 within picoseconds.
Keywords :
Q-factor; micro-optics; mirrors; photonic crystals; Q factor; dynamic control; high-Q photonic-crystal nanocavities; nanocavity systems; nonlinear optical response; photonic-crystal hetero-interface mirror; quantum information processing; ultra-high quality factors; ultrahigh-Q nanocavities; Control systems; Information processing; Lighting control; Nonlinear control systems; Nonlinear dynamical systems; Optical control; Optical waveguide theory; Optical waveguides; Physics; Q factor;
