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"Infrared antennas and resonant structures are examples of the advances achieved during the last two decades based on the electromagnetic interaction of light and a wise combination of material and geometry. These interesting devices can be applied to a variety of fields in optics and photonics, where infrared detection can now overcome the limitations of previous technologies. This book starts with the basics of electromagnetism applicable to the interaction of light with metallic structures having a size comparable to the wavelength, then discusses the special behavior of metals; how to model, design, and validate through simulation of the proposed geometries; how to fabricate the most promising device designs; and various characterization techniques. Then follows a description of the two main types of devices developed by the authors: those producing an electric signal (antenna-coupled devices) and those changing the parameters of the light incident on the resonant elements (resonant optics). The book concludes by discussing challenges currently being addressed and those that might be met in new research and future devices"--
Explains the basics of electromagnetism applicable to the interaction of light with metallic structures having a size comparable to the wavelength, then discusses the special behaviour of metals; how to model, design, and validate through simulation of the proposed geometries; how to fabricate the most promising device designs; and various characterization techniques.
This consistent and systematic review of recent advances in optical antenna theory and practice brings together leading experts in the fields of electrical engineering, nano-optics and nano-photonics, physical chemistry and nanofabrication. Fundamental concepts and functionalities relevant to optical antennas are explained, together with key principles for optical antenna modelling, design and characterisation. Recognising the tremendous potential of this technology, practical applications are also outlined. Presenting a clear translation of the concepts of radio antenna design, near-field optics and field-enhanced spectroscopy into optical antennas, this interdisciplinary book is an indispensable resource for researchers and graduate students in engineering, optics and photonics, physics and chemistry.
This new edition of Infrared and Terahertz Detectors provides a comprehensive overview of infrared and terahertz detector technology, from fundamental science to materials and fabrication techniques. It contains a complete overhaul of the contents including several new chapters and a new section on terahertz detectors and systems. It includes a new tutorial introduction to technical aspects that are fundamental for basic understanding. The other dedicated sections focus on thermal detectors, photon detectors, and focal plane arrays.
Nanophotonics has emerged as a major technology and applications domain, exploiting the interaction of light-emitting and light-sensing nanostructured materials. These devices are lightweight, highly efficient, low on power consumption, and are cost effective to produce. The authors of this book have been involved in pioneering work in manufacturing photonic devices from carbon nanotube (CNT) nanowires and provide a series of practical guidelines for their design and manufacture, using processes such as nano-robotic manipulation and assembly methods. They also introduce the design and operational principles of opto-electrical sensing devices at the nano scale. Thermal annealing and packaging processes are also covered, as key elements in a scalable manufacturing process. Examples of applications of different nanowire based photonic devices are presented. These include applications in the fields of electronics (e.g. FET, CNT Schotty diode) and solar energy. Discusses opto-electronic nanomaterials, characterization and properties from an engineering perspective, enabling the commercialization of key emerging technologies Provides scalable techniques for nanowire structure growth, manipulation and assembly (i.e. synthesis) Explores key application areas such as sensing, electronics and solar energy
This book contains selected articles presented at the 19th International Conference on Global Research and Education, organized by the Francisk Skorina Gomel State University in Gomel, Belarus, Octoter 20–22, 2021. The areas of focus of the book are modern areas of physics and technology, as well as methods and materials of e-learning and online education. It covers areas as plasma physics, bioengineering, solid state physics, nanoelectronics, photonics, environmental design, compositional structures and metamaterials, robotics and metrology, computer physics, online education and e-learning.
Plasmonic structures open up new opportunities in photonic devices, sometimes offering an alternate method to perform a function and sometimes offering capabilities not possible with standard optics. In this LDRD we successfully demonstrated metal coatings on optical surfaces that do not adversely affect the transmission of those surfaces at the design frequency. This technology could be applied as an RF noise blocking layer across an optical aperture or as a method to apply an electric field to an active electro-optic device without affecting optical performance. We also demonstrated thin optical absorbers using similar patterned surfaces. These infrared optical antennas show promise as a method to improve performance in mercury cadmium telluride detectors. Furthermore, these structures could be coupled with other components to lead to direct rectification of infrared radiation. This possibility leads to a new method for infrared detection and energy harvesting of infrared radiation.
The membrane is an intricately structured entity that performs numerous vital biological functions, including materials transport, signal transduction, energy transfer, and enzymatic reactions. Abnormal expression and distribution of certain membrane proteins are even associated with genetic disorders, neurodegenerative diseases, and malignant tumors. Despite the widely acknowledged significance of membranes, comprehensive and systematic research on membranes akin to genomics, proteomics, and metabolomics is still lacking. Furthermore, the broad concept of biomembranes is not confined to the plasma membrane alone; it also includes organelle membranes and membranes of endocytosis or exocytosis vesicles, which are also derived from the biomembrane system. This book introduces the concept of "omics" to membranes and proposes the term ‘biomembranomics.’ It compiles the latest advancements in structural analysis techniques for biomembranes, including single-molecule manipulation techniques, single-molecule fluorescence techniques, super-resolution fluorescence imaging, cryo-electron microscopy, mass spectrometry, molecular dynamics simulation, and hyphenated instrumental techniques. The book presents both classic and cutting-edge protocols in text and illustrative forms, serving as a valuable and applicable reference material. It provides a profound understanding of biomembrane organization at single-molecule level, paving new avenues for unveiling the relationship between membrane structure and function. Therefore, this book is essential reading for researchers across all related fields.
Tapered slot antennas (TSAs) have seen considerable application in the millimeter-wave portion of the spectrum. Desirable characteristics of TSAs include symmetric E- and H-plane antenna patterns, and broad non-resonant bandwidths. We investigate extension of TSA operation toward higher frequencies in the thermal infrared (IR), using a metal-oxide-metal diode as the detector. Several different infrared TSA design forms are fabricated using electron-beam lithography and specially developed thin-film processes. The angular antenna patterns of TSA-coupled diodes are measured at 10.6 micrometer wavelength in both E- and H-planes, and are compared to results of finite-element electromagnetic modeling using Ansoft HFSS. Parameter studies are carried out, correlating the geometric and material properties of several TSA design forms to numerical-model results and to measurements. A significant increase in antenna gain is noted for a dielectric-overcoat design. The traveling-wave behavior of the IR TSA structure is investigated using scattering near-field microscopy. The measured near-field data is compared to HFSS results. Suggestions for future research are included.