Tailoring Plasmon-enhanced Light-matter Interaction
| Author | : Sven Niclas Tebogo Müller |
| Publisher | : |
| Total Pages | : |
| Release | : 2019 |
| Genre | : |
| ISBN | : |
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Plasmon-enhanced light-matter interactions
| Author | : Peng Yu |
| Publisher | : Springer Nature |
| Total Pages | : 348 |
| Release | : 2022-03-01 |
| Genre | : Science |
| ISBN | : 303087544X |
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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.
Plasmonic Control of Light Emission
| Author | : Young Chul Jun |
| Publisher | : Stanford University |
| Total Pages | : 138 |
| Release | : 2010 |
| Genre | : |
| ISBN | : |
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Enhanced light-matter interactions in light-confining structures (such as optical cavities) have been extensively investigated for both fundamental studies and practical applications. Plasmonic nanostructures, which can confine and manipulate light down to ~1 nm scale, are becoming increasingly important. Many areas of optical physics and devices can benefit from such extreme light concentration and manipulation. For example, fluorescent molecule or quantum dot (QD) emission can be strongly modified and controlled via surface plasmon polariton (SPP) coupling. In this dissertation, we present our theoretical and experimental studies on QD emission in metal nanogap structures that can provide extreme field concentration, enhancing light-matter interactions significantly. We start with a theoretical analysis of dipole emission in metal-dielectric-metal (MDM) waveguide structures. We look at both infinite (i.e. planar) and finite thickness MDM structures. We find that both structures exhibit strong spontaneous emission enhancements due to the tight confinement of modes between two metallic plates and that light emission is dominated by gap SPP coupling. For planar structures we present analytical solutions for the enhanced dipole decay rate, while for finite thickness MDM structures (i.e. nanoslits) we present results from numerical simulations. Next, we present our experiments on the SPP coupling of CdSe/ZnS QD emission in metal nanoslits. First, we observed clear lifetime and polarization state changes of QD emission with slit width due to gap SPP excitation. Second, with optimized side grooves (i.e. combined slit-groove and hole-groove structures), we collimated QD emission vertically into a very narrow angle, achieving an unprecedented level of directionality control, and visualized it with confocal scanning microscopy. Third, by using two metal plates as electrodes, we dynamically modulated the QD emission intensity and wavelength with external voltage. Finally, we extend our dipole emission calculation to several slot waveguide structures. We consider light emission in metal slots, metal-oxide-Si slots, and Si slot waveguides. We find that large spontaneous emission enhancements can be obtained over a broad range of wavelengths and that light emission is strongly funneled into slot waveguide modes. These represent broadband waveguide QED (quantum electro-dynamics) systems, which have unique merits for on-chip light sources and quantum information processing. These theoretical and experimental studies show that the SPP coupling of light emission is a very promising way to control light emission properties and may find broad application in spectroscopy, sensing, optoelectronics, and integrated optics.
Plasmonics and Light–Matter Interactions in Two-Dimensional Materials and in Metal Nanostructures
| Author | : Paulo André Dias Gonçalves |
| Publisher | : Springer Nature |
| Total Pages | : 232 |
| Release | : 2020-03-19 |
| Genre | : Science |
| ISBN | : 3030382915 |
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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.
Nanophotonics for Tailoring Light-matter Interaction
| Author | : Wenjun Qiu |
| Publisher | : |
| Total Pages | : 112 |
| Release | : 2013 |
| Genre | : |
| ISBN | : |
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In this thesis, we will theoretically explore three nanophotonics phenomena which enable strong light-matter interaction. The first phenomenon is plasmonic resonance, where the surface plasmon mode at metal and dielectric boundaries significantly enhances the optical response of nanoparticles. We propose an optimization-based theoretical approach to tailor the optical response of silver/silica multilayer nanospheres over the visible spectrum. We show that the structure that provides the largest cross-section per volume/mass, averaged over a wide frequency range, is the silver coated silica sphere. We also show how properly chosen mixture of several species of different nanospheres can have an even larger minimal cross-section per volume/mass over the entire visible spectrum. The second phenomenon is photonic chiral edge state, where the breaking of time-reversal symmetry forces light to travel in only one direction. Based on the directional coupling between one-way waveguide and conventional two-waveguide, we propose a new type of optical circulators, which has the potential for simultaneous broadband operation and small device footprint. The third phenomenon is Stimulated Brillouin Scattering (SBS), where photon and phonon are coupled through optical forces such as electrostriction force and radiation pressure. We develop a general method of calculating SBS gain via the overlap integral between optical and elastic modes. Applying this method to a rectangular waveguide, we demonstrate that the distribution of optical force and elastic modal profile jointly determine the magnitude and scaling of SBS gains. Applying this method to a periodic waveguide, we demonstrate that SBS gain can be further enhanced in the slow light regime. Based on this framework, we theoretically characterize a novel class of hybrid photon-phonon waveguides. Our analysis reveals that photon-phonon coupling via SBS can be directed and tailored over an exceptionally wide frequency range, enabling a host of chip-scale filtering, delay, and signal processing schemes.
Plasmonic Control of Light Emission
| Author | : Young Chul Jun |
| Publisher | : |
| Total Pages | : |
| Release | : 2010 |
| Genre | : |
| ISBN | : |
Download Plasmonic Control of Light Emission Book in PDF, ePub and Kindle
Enhanced light-matter interactions in light-confining structures (such as optical cavities) have been extensively investigated for both fundamental studies and practical applications. Plasmonic nanostructures, which can confine and manipulate light down to ~1 nm scale, are becoming increasingly important. Many areas of optical physics and devices can benefit from such extreme light concentration and manipulation. For example, fluorescent molecule or quantum dot (QD) emission can be strongly modified and controlled via surface plasmon polariton (SPP) coupling. In this dissertation, we present our theoretical and experimental studies on QD emission in metal nanogap structures that can provide extreme field concentration, enhancing light-matter interactions significantly. We start with a theoretical analysis of dipole emission in metal-dielectric-metal (MDM) waveguide structures. We look at both infinite (i.e. planar) and finite thickness MDM structures. We find that both structures exhibit strong spontaneous emission enhancements due to the tight confinement of modes between two metallic plates and that light emission is dominated by gap SPP coupling. For planar structures we present analytical solutions for the enhanced dipole decay rate, while for finite thickness MDM structures (i.e. nanoslits) we present results from numerical simulations. Next, we present our experiments on the SPP coupling of CdSe/ZnS QD emission in metal nanoslits. First, we observed clear lifetime and polarization state changes of QD emission with slit width due to gap SPP excitation. Second, with optimized side grooves (i.e. combined slit-groove and hole-groove structures), we collimated QD emission vertically into a very narrow angle, achieving an unprecedented level of directionality control, and visualized it with confocal scanning microscopy. Third, by using two metal plates as electrodes, we dynamically modulated the QD emission intensity and wavelength with external voltage. Finally, we extend our dipole emission calculation to several slot waveguide structures. We consider light emission in metal slots, metal-oxide-Si slots, and Si slot waveguides. We find that large spontaneous emission enhancements can be obtained over a broad range of wavelengths and that light emission is strongly funneled into slot waveguide modes. These represent broadband waveguide QED (quantum electro-dynamics) systems, which have unique merits for on-chip light sources and quantum information processing. These theoretical and experimental studies show that the SPP coupling of light emission is a very promising way to control light emission properties and may find broad application in spectroscopy, sensing, optoelectronics, and integrated optics.
Manipulation of Light-matter Interaction in Two-dimensional Systems Via Localized Surface Plasmons
| Author | : Joohee Park |
| Publisher | : |
| Total Pages | : 198 |
| Release | : 2015 |
| Genre | : |
| ISBN | : |
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Localized surface plasmons (LSPs), which are collective charge oscillation confined by metallic nanoparticles, gained much interest in the field of optoelectronics due to its ability to confine light down to nanoscale without a diffraction limit. As light-matter interaction in nanoscale is becoming more important due to the demand in scaling down the optoelectronic devices, my thesis describes the work on manipulation of such light-matter interaction enabled by LSPs. First, periodically patterned two-dimensional arrays of bowties were investigated to study the localized surface plasmon (LSP) resonances via reflection measurements and numerical simulations. Due to the grating created by arrays of bowties, a new, lattice-coupled LSP (lattice-LSP) mode emerged. Comparing the calculated E-field enhancement of the bowtie arrays to the reflection spectra showed that the lattice-LSP mode positions are closely related to the dips in the reflectance spectra. After the study of bowtie arrays, we showed photoluminescence (PL) from bulk, planar silicon coupled with metal bowtie nanocavities, which is an indirect bandgap semiconductor with very low emission efficiency. This was due to the E-field concentrated inside the tips of the metal bowtie achieved by LSPR, leading to increased radiative decay rate. The approach of bowtie-coupled emitter was also applied to monolayer MoS2, a transition metal dichalcogenide semiconductor which transforms to a direct bandgap semiconductor in monolayer. Silver bowtie array coupled with monolayer of MoS2 showed a high enhancement in emission (Raman and PL) due to surface-enhanced fluorescence (SEF) from weak-coupling of MoS2 excitons and bowtie's LSPR. By tailoring the design of bowtie arrays, we controlled the location of surface plasmon resonances which, coupled with MoS2 excitons, led to spectral modification of PL spectra. Furthermore, at low temperature, we achieved stronger coupling between the two systems in some designs of the bowtie array and observed Fano resonances in reflection measurements. The approach was extended to photocurrent studies in MoS2. Utilizing the helicity of monolayer MoS2 is suggested as future work to investigate the circular photocurrent in MoS2 induced by selective linear polarizations. Lastly, by fabricating nanoribbon arrays of fluorographene, evolution of localized surface plasmon mode of graphene in near-infrared wavelength range was studied via Fourier transform infrared spectroscopy (FTIR). The initial result showed possibility of tunable graphene IR plasmon resonance depending on the array design due to the localized surface plasmon mode created by the grating of alternating fluoro-graphene and graphene nanoribbons, confining E- field to excite the plasmon modes in IR range.
Tailoring Plasmon Enhanced Fluorescence Near Single Ag Nanoprisms
| Author | : Keiko Munechika |
| Publisher | : |
| Total Pages | : 122 |
| Release | : 2010 |
| Genre | : Nanoparticles |
| ISBN | : |
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Plasmonics
| Author | : Stefan Enoch |
| Publisher | : Springer |
| Total Pages | : 331 |
| Release | : 2012-06-30 |
| Genre | : Science |
| ISBN | : 364228079X |
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This book deals with all aspects of plasmonics, basics, applications and advanced developments. Plasmonics is an emerging field of research dedicated to the resonant interaction of light with metals. The light/matter interaction is strongly enhanced at a nanometer scale which sparks a keen interest of a wide scientific community and offers promising applications in pharmacology, solar energy, nanocircuitry or also light sources. The major breakthroughs of this field of research originate from the recent advances in nanotechnology, imaging and numerical modelling. The book is divided into three main parts: extended surface plasmons polaritons propagating on metallic surfaces, surface plasmons localized on metallic particles, imaging and nanofabrication techniques. The reader will find in the book: Principles and recent advances of plasmonics, a complete description of the physics of surface plasmons, a historical survey with emphasize on the emblematic topic of Wood's anomaly, an overview of modern applications of molecular plasmonics and an extensive description of imaging and fabrications techniques.
Manipulating Light-Matter Interactions in Two-Dimensional Semiconductors Coupled with Plasmonic Lattices
| Author | : Wenjing Liu |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2017 |
| Genre | : |
| ISBN | : |
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Understanding and tailoring light-matter interactions is critical to many fields, offering valuable insights into the nature of materials, as well as allowing a variety of applications such as detectors, sensors, switches, modulators, and lasers. While reducing the optical mode volume is critical to enhancing the light-matter interaction strength, plasmonic systems, with their extraordinary ability to confine the light far below the diffraction limit of light, provide intriguing platforms in boosting the light-matter interactions at nanoscale.On the other hand, atomically thin semiconductors such as few-layered transition metal dichalcogenides (TMDs), a recently discovered class of materials, exhibit unique optical properties such as large exciton binding energies, tightly-bond trion excitations, and valley-spin locking, allowing the observations of interesting photonic and electronic phenomena including strong photon-exciton coupling, valley Zeeman and valley optical Stark effect, valley Hall effect, and spin light emitting, hence serve as great candidates to study light-matter interactions in two dimensional systems.In this thesis, combining the two intriguing optical and material systems, we study light-matter interactions between 2D semiconductors and 2D plasmonic lattices, due to their compatibility with 2D semiconductors as well as strong and highly tunable plasmonic resonances. We investigated exciton-plasmon coupling by integrating MoS2 with plasmonic lattices of various geometrical designs and observed rich phenomena in different coupling regimes.We will first present a detailed study of observing exciton-plasmon coupling in weak, intermediate and strong coupling regimes via different plasmonic lattice design. We've demonstrated large Purcell enhancement in weak coupling regime, and Fano resonances in intermediate coupling regime, and exciton-plasmon polariton formation in strong coupling regime. After that, we will discuss active tuning of the coupling strengths all the way across the weak and strong coupling regime via electrical gating. Finally, we will demonstrate chiral exciton-plasmon coupling by designing chiral plasmonic lattices.
