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Plasmonics is an important branch of optics concerned with the interaction of metals with light. Under appropriate illumination, metal nanoparticles can exhibit enhanced light absorption, becoming nanosources of heat that can be precisely controlled. This book provides an overview of the exciting new field of thermoplasmonics and a detailed discussion of its theoretical underpinning in nanophotonics. This topic has developed rapidly in the last decade, and is now a highly-active area of research due to countless applications in nanoengineering and nanomedicine. These important applications include photothermal cancer therapy, drug and gene delivery, nanochemistry and photothermal imaging. This timely and self-contained text is suited to all researchers and graduate students working in plasmonics, nano-optics and thermal-induced processes at the nanoscale.
Current Trends and Future Developments on (Bio-) Membranes: Membrane Desalination Systems: The Next Generation explores recent developments and future perspectives in the area of membrane desalination systems. It includes fundamental principles, the different types of smart nano-structured materials, energy and brine disposal issues, design approaches and the environmental impact of membrane desalination technology. The book provides an extensive review of literature in the area of membranes for desalination systems of low energy consumption and discusses the membrane modelling necessary for desalination system validation in achieving high water recovery, low energy and near-zero liquid discharge. - Outlines the use of the potential of salinity gradient power from brines for a low-energy desalination concept - Focuses on the development of integrated membrane systems to achieve the goal of near-zero-liquid-discharge - Summarizes the latest advancement in the nanosciences for creating membranes with advanced properties and functions
What is a plasmon? Is it a particle, like a photon or a wave? Plasmonics stands at the frontier of condensed matter physics, which is the world of electrons, optics and of photons. Plasmonics is one of the most active fields in nanophotonics. This book begins by exploring the concepts behind waves, and the electromagnetic description of light when it interacts with metals; it dedicates every chapter thereafter to all aspects of plasmonics. In particular, the surface plasmon polariton wave is explained in full detail, as well as the localized surface plasmon resonance of metallic nanoparticles. The active research area opened by plasmonics, as well as its applications, are also briefly explained, such as advanced biosensing, subwavelength waveguiding, quantum plasmonics, nanoparticle-based cancer therapies, optical nano-antenna and high-efficiency photovoltaic cells.The book is adapted for graduate students and places a special emphasis on providing complete explanations of the fundamental concepts of plasmonics. Further, each of these concepts is illustrated with examples drawn from the most recent scientific literature. Each chapter ends with a set of exercises that will help the reader revise the concepts and go deeper into the world of plasmonics. More than 70 exercises are included.
About this book This book features a collection of reviews focusing on interrelated topics in nano-optics and nanophononics written by some of the world's leading scientists in these fields. The book discusses recent results of numerical investigations of light-matter interactions at the nanoscale using first-principles calculations. Additionally, it reviews selected topics in the areas of nanophotonic devices based on functional nanoparticles for energy harvesting and the development of photo materials for advanced applications in optics and nanotechnologies. Finally, the book reviews the experimental development of quantum-dot single-photon sources on integrated photonic circuits and looks at applications in quantum information processing and quantum information distribution based on color center in diamond.
Erik Wischerhoff, Nezha Badi, André Laschewsky and Jean-François Lutz Smart Polymer Surfaces: Concepts and Applications in Biosciences; S. Petersen, M. Gattermayer and M. Biesalski Hold on at the Right Spot: Bioactive Surfaces for the Design of Live-Cell Micropatterns; Julien Polleux Interfacing Cell Surface Receptors to Hybrid Nanopatterned Surfaces: A Molecular Approach for Dissecting the Adhesion Machinery; Abigail Pulsipher and Muhammad N. Yousaf Self-Assembled Monolayers as Dynamic Model Substrates for Cell Biology; D. Volodkin, A. Skirtach and H. Möhwald LbL Films as Reservoirs for Bioactive Molecules; R. Gentsch and H. G. Börner Designing Three-Dimensional Materials at the Interface to Biology; Joerg C. Tiller Antimicrobial Surfaces;
The exploration of photothermal nanomaterials with high light-to-heat conversion efficiency has paved the way for practical applications, including in cancer therapy, environmental remediation, catalysis, imaging and biomedicine. Covering the photothermal effect of different categories of light-absorbing nanomaterials, and focusing on metallic nanomaterials, 2D materials, semiconductors, carbon-based nanomaterials, polymeric nanomaterials and their composites, chapters in this book provide a systematic summary of recent advances in the fabrication and application of photothermal nanomaterials, discussing advantages, challenges and potential opportunities. This text will be a valuable resource for scientists working on photothermal nanomaterials, as well as those interested in the applications across chemistry, biomedicine, nanotechnology and materials science.
During the last few years, nanomaterials have attracted the attention of the scientific community due to their extraordinary and unique properties. Their small size, and the distinctive features that come with it, makes these materials very attractive for use in different important fields like biomedicine, sensors, or catalysis. One of the most important properties of these materials is their interaction with light and is called surface plasmon resonance. It is a phenomenon that happens on the surface of certain nanomaterials that confers them with unique properties. This remarkable characteristic has opened a whole new field called nanoplasmonics that is acquiring more and more importance among the scientific community. This book aims to review the state of the art in this new field and provide the reader with a wide overview of the new nanomaterials available and their current and future applications.
A state-of-the-art examination of biomedical photonic research, technologies, and applications In Biomedical Photonic Technologies, a team of distinguished researchers delivers a methodical inquiry and evaluation of the latest developments in the field of biomedical photonics, with a focus on novel technologies, including optical microscopy, optical coherence tomography, fluorescence imaging-guided surgery, photodynamic therapy dosimetry, and optical theranostic technologies. Each discussion of individual technologies includes examples of their contemporary application in areas like cancer therapy and drug delivery. Readers will discover the major research advancements in biomedical photonics from the last 20 years, ascertaining the basic principles of formation, development, and derivation of biomedical photonics phenomena at a variety of scales. Readers will also find: A thorough introduction to advanced wide-field fluorescent microscopy for biomedicine Comprehensive explorations of fluorescence resonance energy transfer and optical coherence tomography for structural and functional imaging Practical exploration of coherent Raman scattering microscopy and biomedical applications, as well as fluorescence image-guided surgery Complete analyses of enhanced photodynamic therapy, optogenetics, and optical theranostics employing gold nanoparticles Perfect for biophysicists and applied physicists, Biomedical Photonic Technologies will also benefit bioengineers and biotechnologists in academia and in industry.
Electrochemistry and Photo-Electrochemistry of Nanomaterials: Fundamentals and Applications explores how nanotechnology and nanomaterials can be utilized in the field of electrochemistry and photo-electrochemistry. The book covers the fundamentals of nanoscale electrochemistry and photo-electrochemistry for nanoscale materials systems, including multilayer nanofilms, nanowires, nanotubes, nanoparticles embedded in metal matrixes, and membranes containing nanoparticles. The creation of new materials for energy and sensing technologies that rely on understanding and control of chemical processes is also emphasized. Advances in characterization, synthesis, and fabrication of nanoscale materials and technologies are also discussed regarding the design of new materials. This book is suitable for academics and industry professionals working in the subject areas of materials science, materials chemistry, inorganic chemistry, and energy. - Reviews fundamental concepts of electrochemistry and photo-electrochemistry for nanoscale materials systems - Includes the electrochemical techniques to synthesize, characterize, and control and improve the properties of nanoscale material systems - Discusses the latest research directions to design new materials for energy and sensing applications
Metamaterials represent a new emerging innovative field of research which has shown rapid acceleration over the last couple of years. In this handbook, we present the richness of the field of metamaterials in its widest sense, describing artificial media with sub-wavelength structure for control over wave propagation in four volumes.Volume 1 focuses on the fundamentals of electromagnetic metamaterials in all their richness, including metasurfaces and hyperbolic metamaterials. Volume 2 widens the picture to include elastic, acoustic, and seismic systems, whereas Volume 3 presents nonlinear and active photonic metamaterials. Finally, Volume 4 includes recent progress in the field of nanoplasmonics, used extensively for the tailoring of the unit cell response of photonic metamaterials.In its totality, we hope that this handbook will be useful for a wide spectrum of readers, from students to active researchers in industry, as well as teachers of advanced courses on wave propagation.