Description
Book SynopsisThe rapid advancement of integrated optoelectronics has been driven considerably by miniaturization. Following the path taken in electronics of reducing devices to their ultimately fundamental forms, for instance single-electron transistors, now optical devices have also been scaled down, creating the increasingly active research fields of integrated and coupled photonic systems. The interactions between the coupled integrated micro- and nanostructures can provide us with the fundamental understanding and engineering of complex systems for a variety of applications.
This book aims to bring to the readers the latest developments in the rapidly emerging field of integrated nanophotonic resonators and devices. It compiles cutting-edge research from leading experts who form an interdisciplinary team around the world. The book also introduces the fundamental knowledge of coupled integrated photonic/electronic/mechanical micro- and nanoresonators and their interactions, as well as advanced research in the field.
Trade Review"This unique book introduces readers to the rapid advancement in a variety of active areas in coupled and integrated nanophotonics. All the chapters represent the latest cutting-edge research in this emerging field. Readers from both academia and industry who are interested in integrated nanophotonic resonators and devices will definitely benefit from this timely book."
— Dr. Terry L. Smith, 3M Co., USA
"This is a leading book in the field of nanophotonic resonators and devices and presents the latest developments. Integrated nanophotonics will play a pivotal role in future semiconductor chips, and this text provides scientists, engineers, and professionals with invaluable resources in this cutting-edge field."
— Dr. Xiaoman Duan, Massachusetts Institute of Technology, USA
"In this book, some typical topics in the field of integrated nanophotonic resonators are reviewed from the point of view of fundamentals, devices, and applications. The emerging new advances in integrated microresonators, optoplasmonics, silicon-based photonic devices, optomechanical systems, optical trapping, and photonic-structured scintillators and the theoretical simulation methods described in this book will open the door to realizing an unprecedented development. Undoubtedly, this book is beneficial to this community."
— Prof. Hong Chen, Tongji University, China
"This unique book introduces readers to the rapid advancement in a variety of active areas in coupled and integrated nanophotonics. All the chapters represent the latest cutting-edge research in this emerging field. Readers from both academia and industry who are interested in integrated nanophotonic resonators and devices will definitely benefit from this timely book."
— Dr. Terry L. Smith, 3M Co., USA
"This is a leading book in the field of nanophotonic resonators and devices and presents the latest developments. Integrated nanophotonics will play a pivotal role in future semiconductor chips, and this text provides scientists, engineers, and professionals with invaluable resources in this cutting-edge field."
— Dr. Xiaoman Duan, Massachusetts Institute of Technology, USA
"In this book, some typical topics in the field of integrated nanophotonic resonators are reviewed from the point of view of fundamentals, devices, and applications. The emerging new advances in integrated microresonators, optoplasmonics, silicon-based photonic devices, optomechanical systems, optical trapping, and photonic-structured scintillators and the theoretical simulation methods described in this book will open the door to realizing an unprecedented development. Undoubtedly, this book is beneficial to this community."
— Prof. Hong Chen, Tongji University, China
Table of ContentsHybrid and coupled photonic system between nanoparticle and integrated micro resonator. Coupled mode theory and its applications in computational nanophotonics. Template-guided self-assembly of discrete optoplasmonic molecules and extended optoplasmonic arrays. Nanophotonic resonators for enhancement of absorption and transmission cross sections of subwavelength plasmonic devices. Photoluminescent centers interacting with silicon-based photonic devices. Nonclassical light sources and frequency converters with integrated optomechanical systems. Scintillators boosted by nanophotonics. Optical trapping of nanoparticles. Rainbow trapping effect in horizontal and vertical directions.
