Dynamic Control Of Light In On Chip Microresonators
Download Dynamic Control Of Light In On Chip Microresonators PDF/ePub or read online books in Mobi eBooks. Click Download or Read Online button to get Dynamic Control Of Light In On Chip Microresonators book now. This website allows unlimited access to, at the time of writing, more than 1.5 million titles, including hundreds of thousands of titles in various foreign languages.
Dynamic Control of Light in On-chip Microresonators
Optical microresonators have generated much progress in many aspects of optical science, such as in optical buffering, wavelength division-multiplexed filters for optical networks, optical switching, and in the enhancement of nonlinear effects. All these applications are made possible by the confinement of light within a small modal volume in the microresonator. The ability to actively tune the resonance within a microresonator has resulted in systems that can dynamically manipulate the flow of light. This thesis discusses some of the novel capabilities of these dynamic systems. Chapters 3 - 4 discusses the use of a dynamic delay line to suppress dispersion, and to overcome the gain-bandwidth product constraint of slow-light structures. This is followed by Chapter 5 which introduces a light-stopping scheme based on loss modulation. Finally, Chapter 6 shows how coherent control can be used in a microresonator system to enhance optical switching.
Dynamic Control of Light in On-chip Microresonators
Optical microresonators have generated much progress in many aspects of optical science, such as in optical buffering, wavelength division-multiplexed filters for optical networks, optical switching, and in the enhancement of nonlinear effects. All these applications are made possible by the confinement of light within a small modal volume in the microresonator. The ability to actively tune the resonance within a microresonator has resulted in systems that can dynamically manipulate the flow of light. This thesis discusses some of the novel capabilities of these dynamic systems. Chapters 3 - 4 discusses the use of a dynamic delay line to suppress dispersion, and to overcome the gain-bandwidth product constraint of slow-light structures. This is followed by Chapter 5 which introduces a light-stopping scheme based on loss modulation. Finally, Chapter 6 shows how coherent control can be used in a microresonator system to enhance optical switching.
Practical Applications of Microresonators in Optics and Photonics
Assembling an international team of experts, this book reports on the progress in the rapidly growing field of monolithic micro- and nanoresonators. The book opens with a chapter on photonic crystal-based resonators (nanocavities). It goes on to describe resonators in which the closed trajectories of light are supported by any variety of total internal reflection in curved and polygonal transparent dielectric structures. The book also covers distributed feedback microresonators for slow light, controllable dispersion, and enhanced nonlinearity. A portion of coverage is dedicated to the unique properties of resonators, which are extremely efficient tools when conducting multiple applications.