Author: Nasim Mohammadi Estakhri
Publisher:
ISBN:
Category :
Languages : en
Pages : 412
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Book Description
The interaction of electromagnetic waves with materials is at the basis of several phenomena influencing our everyday lives. Throughout the past few decades we are witnessing a rapid progress in the development of new platforms to engineer and design different aspects of wave-matter interaction for applications ranging from green energy harvesting, to high speed data communication, and medicine. In line with these developments, the advent of metamaterials, or artificially structured materials, introduces an alternative path to mold and control electromagnetic waves with degrees of freedom that are not accessible in natural materials. There is, however, a strong need to broaden the range of applicability of metamaterials thorough strong nanoscale light management, real-time tunability, ease of fabrication, and lowering the losses. In this study we discuss that to what extent it is possible to engineer the scattering, absorption, and local wave-matter interaction of metamolecules, as the basic building-blocks of metamaterials, as well as assembles of them forming complex systems. In this work, first, we propose and investigate new nanoparticle geometries with tailored complex absorption and scattering signatures. We demonstrate that plasmonic-based nanostructures can be tailored to provide unprecedented control of their scattering and absorption/emission response over broad bandwidths, specifically in the optical frequency range. We show that judicious combination of plasmonic-dielectric singular nanoparticles provides very efficient broadband and controllable light absorption and amplification. Based on these composite elements, we propose a nanoscale optical switch with strong sensitivity and tunability. These engineered nanoparticles are also particularly interesting for applications in nonlinear optics, spasing, and energy-harvesting devices. Next, we answer the fundamental question of "to what extent the unwanted scattering from a general absorbing body may be reduced?". We demonstrate the theoretical limitations of a furtive sensor and provide a proof of the concept implementation of minimum-scattering superabsorbers at optical and microwave frequencies. Based on our theoretical analysis, we also explore experimental realization of microwave low-scattering antennas. This study is of particular importance for the near-field subdiffractive probing and closely-packed antenna designs. Last, we propose a new degree of freedom in controlling the propagation and scattering of light through proper arrangements of dissimilar metamolecules over a surface, i.e. gradient metasurfaces. We theoretically investigate and design metasurfaces that are capable of performing complex wave shaping functionalities such as cloaking, yet, over a single ultrathin volume. Our full analytical approach enables us to underline the inherent limitations and wide range of capabilities of metasurfaces, and we propose novel techniques to significantly improve the efficiency of wave manipulation by metasurfaces. We also investigate the proposed concept of local wave manipulation in several practical applications in beam steering, improved energy harvesting, and cloaking arbitrary obstacles, accompanied by experimental realization of negative reflection from optical metasurfaces. Such unprecedented control of optical wave propagation along with compatibility of metasurfaces with standard lithographic techniques and on-chip technology will significantly impact the future application of metasurfaces, paving the way toward flat, compact optical devices.
Author: Peng Yu
Publisher: Springer Nature
ISBN: 303087544X
Category : Science
Languages : en
Pages : 348
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Book Description
This book highlights cutting-edge research in surface plasmons, discussing the different types and providing a comprehensive overview of their applications. Surface plasmons (SPs) receive special attention in nanoscience and nanotechnology due to their unique optical, electrical, magnetic, and catalytic properties when operating at the nanoscale. The excitation of SPs in metal nanostructures enables the manipulation of light beyond the diffraction limit, which can be utilized for enhancing and tailoring light-matter interactions and developing ultra-compact high-performance nanophotonic devices for various applications. With clear and understandable illustrations, tables, and descriptions, this book provides physicists, materials scientists, chemists, engineers, and their students with a fundamental understanding of surface plasmons and device applications as a basis for future developments.
Author: Paulo André Dias Gonçalves
Publisher: Springer Nature
ISBN: 3030382915
Category : Science
Languages : en
Pages : 232
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Book Description
This thesis presents a comprehensive theoretical description of classical and quantum aspects of plasmonics in three and two dimensions, and also in transdimensional systems containing elements with different dimensionalities. It focuses on the theoretical understanding of the salient features of plasmons in nanosystems as well as on the multifaceted aspects of plasmon-enhanced light–matter interactions at the nanometer scale. Special emphasis is given to the modeling of nonclassical behavior across the transition regime bridging the classical and the quantum domains. The research presented in this dissertation provides useful tools for understanding surface plasmons in various two- and three-dimensional nanostructures, as well as quantum mechanical effects in their response and their joint impact on light–matter interactions at the extreme nanoscale. These contributions constitute novel and solid advancements in the research field of plasmonics and nanophotonics that will help guide future experimental investigations in the blossoming field of nanophotonics, and also facilitate the design of the next generation of truly nanoscale nanophotonic devices.
Author: Hongxing Xu
Publisher: CRC Press
ISBN: 1351767585
Category : Science
Languages : en
Pages : 240
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Book Description
The manipulation of light at the nanometer scale is highly pursued for both fundamental sciences and wide applications. The diffraction limit of light sets the limit for the smallest size of photonic devices to the scale of light wavelength. Fortunately, the peculiar properties of surface plasmons in metal nanostructures make it possible to squeeze light into nanoscale volumes and enable the manipulation of light and light–matter interactions beyond the diffraction limit. Studies on surface plasmons have led to the creation of a booming research field called plasmonics. Because of its various scientific and practical applications, plasmonics attracts researchers from different fields, making it a truly interdisciplinary subject. Nanophotonics: Manipulating Light with Plasmons starts with the general physics of surface plasmons and a brief introduction to the most prominent research topics, followed by a discussion of computational techniques for light scattering by small particles. Then, a few special topics are highlighted, including surfaceenhanced Raman scattering, optical nanoantennas, optical forces, plasmonic waveguides and circuits, and gain-assisted plasmon resonances and propagation. The book discusses the fundamental and representative properties of both localized surface plasmons and propagating surface plasmons. It explains various phenomena and mechanisms using elegant model systems with well-defined structures, is illustrated throughout with excellent figures, and contains an extensive list of references at the end of each chapter. It will help graduate-level students and researchers in nanophotonics, physics, chemistry, materials science, nanoscience and nanotechnology, and electrical and electronic engineering get a quick introduction to this field.
Author: Jennifer M. Reed
Publisher:
ISBN:
Category :
Languages : en
Pages : 198
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Book Description
Lastly, in Chapter 5, the effect of surface plasmons on the propagation direction of electromagnetic wave around a spherical silver nanoparticle which shows an effective negative index of refraction is examined. In addition, light manipulation using a film of silver prisms with an effective negative index of refraction is also investigated. The silver prisms demonstrate polarization selective propagation for waveguide and optical filter applications. These studies provide insight into plasmonic mechanisms utilized to overcome the diffraction limit of light. Through better understanding of how to manipulating light with plasmonic nanostructures, further advancements in nanophotonic technologies for applications such as extremely subwavelength waveguides, sensitive optical detection, optical filters, polarizers, beam splitters, optical data storage devices, high speed data transmission, and integrated subwavelength photonic circuits can be achieved.
Author: Yang Zhao
Publisher:
ISBN:
Category :
Languages : en
Pages : 354
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Book Description
Metals interact very differently with light than with radio waves and finite conductivities and losses often limit the way that RF concepts can be directly transferred to higher frequencies. Plasmonic materials are investigated here for various optical applications, since they can interact, confine and focus light at the nanoscale; however, regular plasmonic devices are severely limited by frequency dispersion and absorption, and confined signals cannot travel along plasmonic lines over few wavelengths. For these reasons, novel concepts and materials should be introduced to successfully manipulate and radiate light in the same flexible way we operate at lower frequencies. In line with these efforts, optical metamaterials exploit the resonant wave interaction of collections of plasmonic nanoparticles to produce anomalous light effects, beyond what naturally available in optical materials and in their basic constituents. Still, these concepts are currently limited by a variety of factors, such as: (a) technological challenges in realizing 3-D bulk composites with specific nano-structured patterns; (b) inherent sensitivity to disorder and losses in their realization; (c) not straightforward modeling of their interaction with nearby optical sources. In this study, we develop a novel paradigm to use single-element nanoantennas, and composite nanoantenna arrays forming two-dimensional metasurfaces and three-dimensional metamaterials, to control and manipulate light and its polarization at the nanoscale, which can possibly bypass the abovementioned limitations in terms of design procedure and experimental realization. The final design of some of the metamaterial concepts proposed in this work was inspired by biological species, whose complex structure can exhibit superior functionalities to detect, control and manipulate the polarization state of light for their orientation, signaling and defense. Inspired by these concepts, we theoretically investigate and design metasurfaces and metamaterial models with the help of fully vectorial numerical simulation tools, and we are able to outline the limitations and ultimate conditions under which the average optical surface impedance concept may accurately describe the complex wave interaction with planar plasmonic metasurfaces. We also experimentally explore various technological approaches compatible with these goals, such as the realization of lithographic single-element nanoantenna and nanoantenna arrays with complex circuit loads, periodic arrays of plasmonic nanoparticles or nanoapertures, and stacks of rotated plasmonic metasurfaces. At the conclusion of this effort, we have theoretically analyzed, designed and experimentally realized and characterized the feasibility of using discrete metasurfaces to realize phenomena and performance that are not available in natural materials, oftentimes inspired by the biological world.
Author: John Weiner
Publisher: Oxford University Press, USA
ISBN: 0198567669
Category : Medical
Languages : en
Pages : 277
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Book Description
This book draws together the essential elements of classical electrodynamics, surface wave physics, plasmonic materials, and circuit theory of electrical engineering to provide insight into the essential physics of nanoscale light-matter interaction and to provide design methodology for practical nanoscale plasmonic devices. A chapter on classical and quantal radiation also highlights the similarities (and differences) between the classical fields of Maxwell's equations and the wave functions of Schrödinger's equation. The aim of this chapter is to provide a semiclassical picture of atomic absorption and emission of radiation, lending credence and physical plausibility to the "rules" of standard wave-mechanical calculations. The structure of the book is designed around five principal chapters, but many of the chapters have extensive "complements" that either treat important digressions from the main body or penetrate deeper into some fundamental issue. Furthermore, at the end of the book are several appendices to provide readers with a convenient reference for frequently-occurring special functions and explanations of the analytical tools, such as vector calculus and phasors, needed to express important results in electromagnetics and waveguide theory.
Author: Seyyed Hossein Mousavi
Publisher:
ISBN:
Category :
Languages : en
Pages : 288
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Book Description
Plasmonics is an important branch of optics and photonics, focusing on the electromagnetic response of metals or other materials with free carriers. This field has recently experienced a significant expansion due to its importance for applications. Plasmonics has shown great promises in green energies, biosensing, nanolasers, and imaging. The main advantage of plasmonics stems from the existence of unique excitations, referred to as plasmons, representing collective response of the free carriers to the electromagnetic field. While plasmons, both in the bulk and on the surface of the metals, have been known for decades, the recent advances in nano fabrication and material sciences at nano scale have enabled versatile engineering of these modes. Focus of my dissertation is surface plasmons whose properties can be tailored by judiciously nano-patterning metal films and surfaces. Such patterned structures, referred to as metasurfaces, are the main tool to control and boost the light-matter interaction. Appropriately designed metasurfaces provide many-fold electromagnetic energy enhancement on the surface which can be used to amplify numerous surface effects such as SEIRA and nonlinear optical phenomena, facilitate spectroscopy, and enhance absorption of light. In this thesis, I report approaches to shape and engineer the confinement, mode profile, and lifetime of the surface modes. I also investigate how the dielectric environment affects the properties of the modes. The effect of the geometry and topology of the nano patterns on the optical response of metasurfaces is also studied. Finally I study how manipulating symmetries of metasurfaces can be used to tailor polarization state of light and lifetime of the modes using an ultrathin metasurface, instead of bulky traditional optical elements. The symmetry manipulation results in the plasmonic analogue of Electromagnetically Induced Transparency, a well-known phenomenon in atomic physics. The work summarized in this thesis has brought marked advances in understanding the physics behind the collective surface waves in nano-structured metasurfaces. It paves new avenues for engineering structures with desirable properties. The immediate application of my findings is the compactification of optical elements, and envisioning next-generation plasmonic-based on-chip devices.
Author: Zilong Wu (Ph. D.)
Publisher:
ISBN:
Category :
Languages : en
Pages : 322
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Book Description
Optical metamaterials and metasurfaces, which are properly designed assembly of man-made building blocks with strong interactions with electromagnetic waves, have emerged as promising candidates to replace natural materials due to extraordinary capabilities in light manipulation. In particular, plasmonic metamaterials and metasurfaces have shown their potentials in surpassing diffraction limit, manipulating light beams, and enhancing energy conversion by substantially enhancing light-matter interactions through effects of surface plasmon polaritons (SPPs) or localized surface plasmons (LSPs). Although enormous breakthroughs in plasmonic metamaterials and metasurfaces have been made in the recent decades, the further development of this field towards practical applications has been limited by the lack of high throughput fabrication and the poor tunability in conventional designs. This dissertation presents the cost-effective nanofabrication, rationale design, numerical modelling, experimental demonstration, and application prototyping of new classes of plasmonic metamaterials and metasurfaces featured by moiré patterns. Firstly, we developed novel techniques based on conventional nanosphere lithography to achieve high-throughput nanofabrication of metamaterials and metasurfaces with three-dimensional (3D) and two-dimensional (2D) moiré configurations. Secondly, we demonstrated multiband moiré metasurfaces with flexible tunability based on plasmonic materials including Au and graphene, which have shown potentials as multifunctional biomedical platforms. Thirdly, we developed moiré chiral metamaterials with ultrathin thickness and precisely tunable chiroptical responses, which have been applied as ultrasensitive sensors to achieve label-free enantiodiscrimination of chiral molecules. Finally, we introduced dynamic tunability in moiré chiral metamaterials through stimuli-responsive manipulation of optical coupling in the metamaterials. The results presented in this dissertation could provide guidance to the development of tunable moiré metamaterials and metasurfaces from design and fabrication to characterization and device implementation, benefiting a range of applications from light manipulation to molecular sensing
Author: MD Imran Khan
Publisher:
ISBN:
Category :
Languages : en
Pages : 276
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Book Description
Plasmonic meta-structure paves the way to study and manipulate light both in far and near filed. Achieving invisibility (cloaking) by suppressing scattering from an object using a nanoassembled 3D plasmonic meta-structure is the principal study of this dissertation. The concept of "cloaking" an object is a very attractive one, especially in the visible (VIS) and near infra-red (NIR) regions of the electromagnetic spectrum, as that would reduce the visibility of an object to the eye. One possible route to achieving this goal is by leveraging the plasmonic property of metallic nanoparticles (NPs). In this dissertation a model was developed to simulate light in the VIS and NIR scattered by a core of a homogeneous medium, covered by plasmonic cloak that is a spherical shell composed of gold nanoparticles (AuNPs). To consider realistic, scalable, and robust plasmonic cloaks that are comparable, or larger, in size to the wavelength, a multiscale simulation platform was introduced. This model uses the multiple scattering theory of Foldy and Lax to model interactions of light with AuNPs combined with the method of fundamental solutions to model interactions with the core. Numerical results of the simulations for the scattering cross-sections of core-shell composite indicate significant scattering suppression of up to 50% over a substantial portion of the desired spectral range (400 - 600 nm) for cores as large as 900 nm in diameter by a suitable combination of AuNP sizes and filling fractions of AuNPs in the shell. Suppressing total scattering cross-section by a plasmonic meta-structure effects the angular distribution of the scattered energy both spectrally and spatially. The second project of this dissertation studies the engineering of spatial and spectral profiles applying the plasmonic meta-structures. The possibility of engineering spectral scattering was explored by three-dimensional mesoscale dielectric targets coated with gold nanoparticles (AuNPs) on the surface. By varying AuNP sizes (5-20 nm) and filling fractions of the AuNP coatings (0.1 - 0.3), simulations reveals that under optimal combination of these two parameters, a meta-structure demonstrates reduced or enhanced scattering efficiency compared to the bare core. Furthermore, analysis of the differential scattering cross-section shows that the presence of the AuNP coating alters the angular distribution of scattering by suppressing the angular sidelobes, thereby guiding the scattered power preferentially in the forward direction. The simulated results highlight that with the ability to tune both the spatial and spectral aspects of the scattering profile, these coated structures may serve as a platform for a variety of applications, including passive cloaking and high-resolution imaging. The final part of this dissertation is the experimental realization of nano assembled 3D plasmonic meta-structures following the demonstration of plasmonic cloaking by these structures. These meta-structures were designed based on the simulated results, they are comprised of a dielectric (silica) core coated with randomly distributed AuNPs. Silica surface modified by the suitable amine ligand enabled adsorption of the AuNPs, and electrostatic interactions between AuNPs promoted nanoscale self-assembly, resulted in robust core-shell structures. Furthermore, the meta-structure fabrication process was optimized to achieve the desired surface coverage (> 20%) of AuNPs for varied meta-structure sizes (500 nm, 700 nm). Measured scattering cross-section of bare silica and AuNP coated silica sphere revealed broadband scattering suppression by the plasmonic meta-structures up to 570 nm in the visible spectrum. Simulated and the measured scattering cross-sections of the bare cores and core-shell structures showed a very good agreement confirming the applicability of the multiscale simulation platform to real-world systems
