Global ETD Search

321	Exciton-plasmon interactions in metal-semiconductor nanostructures Hellström, Staffan January 2012 (has links) Semiconductor quantum dots and metal nanoparticles feature very strong light-matter interactions, which has led to their use in many photonic applications such as photodetectors, biosensors, components for telecommunications etc.Under illumination both structures exhibit collective electron-photon resonances, described in the frameworks of quasiparticles as exciton-polaritons for semiconductors and surface plasmon-polaritons for metals.To date these two approaches to controlling light interactions have usually been treated separately, with just a few simple attempts to consider exciton-plasmon interactions in a system consisting of both semiconductor and metal nanostructures.In this work, the exciton-polaritons and surface \\plasmon-polaritons are first considered separately, and then combined using the Finite Difference Time Domain numerical method coupled with a master equation for the exciton-polariton population dynamics.To better understand the properties of excitons and plasmons, each quasiparticle is used to investigate two open questions - the source of the Stokes shift between the absorption and luminescence peaks in quantum dots, and the source of the photocurrent increase in quantum dot infrared photodetectors coated by a thin metal film with holes. The combined numerical method is then used to study a system consisting of multiple metal nanoparticles close to a quantum dot, a system which has been predicted to exhibit quantum dot-induced transparency, but is demonstrated to just have a weak dip in the absorption. / <p>QC 20120417</p> plasmons excitons quantum dots nanoparticles FDTD surface plasmon polaritons QDIP quantum dot infrared photodetector polaritons
322	Biophysical investigation of M-DNA Wood, David Owen 31 May 2005 M-DNA is a complex formed between normal double-stranded DNA and the transition metal ions Zn2+, Ni2+, and Co2+ that is favoured by an alkaline pH. Previous studies have suggested that M-DNA formation involves replacement of the imino protons of G and T bases by the transition metal ions involved in forming the complex. Owing to the conductive properties of this unique DNA conformation, it has potential applications in nanotechnology and biosensing. This work was aimed at improving existing methods and developing new methods of characterizing M-DNA. The effects of base substitutions, particularly those of G and T, were evaluated in light of the proposed structure. Differences between M-DNA conformations induced by Zn2+ and Ni2+ were also investigated with a variety of techniques and compared to the effects of Cd2+ and Mg2+ on double-stranded DNA. M-DNA formation and stability were studied with an ethidium bromide (EtBr) based assay, M-DNA induced fluorescence quenching of DNA labelled with fluorescein and a compatible quenching molecule, isothermal titration calorimetry (ITC), and surface plasmon resonance (SPR). Production of monoclonal antibodies against the conformation was also attempted but was unsuccessful. The EtBr-based assay showed Ni(II) M-DNA to be much more stable than Zn(II) M-DNA as a function of pH and in the presence of ethylenediaminetetraacetic acid. Sequence-dependency and the effect of base substitutions were measured as a function of pH. With regards to sequence, d(G)nd(C)n tracts were found to form the conformation most easily. Base substitutions with G and T analogues that lowered the pKa of these bases were found to stabilize M-DNA more strongly than other base substitutions. A combination of temperature-dependant EtBr and ITC assays showed M-DNA formation to be endothermic, and therefore entropy driven. The SPR studies demonstrated many qualitative differences between Zn(II) and Ni(II) M-DNA formation, allowed characterization of Zn2+, Ni2+, Cd2+, and Mg2+ complexes with single-stranded DNA, and provided unambiguous evidence that M-DNA formation results in very little denaturation of double-stranded DNA. Specifically, the SPR study showed Ni(II) M-DNA to be more stable than Zn(II) M-DNA in the absence of transition metal ions, but also showed that Ni(II) M-DNA required higher concentrations of Ni2+ than Zn2+ to fully form the respective M-DNA conformations. Finally, quenching studies demonstrated Zn(II) M-DNA formation over a pH range from 6.5 to 8.5 provided that a Zn2+:H+ ratio of roughly 105 was maintained. The Keq for this interaction was 1.3 x 10-8 with 1.4 H+ being liberated per base bair of M-DNA formed. These results support the proposed structural model of M-DNA, as lowering the pKa of the bases having titratable protons over the pH range studied facilitated M-DNA formation. The fact that Zn(II) M-DNA formation was observed by fluorescence quenching at any pH provided that a constant ratio of Zn2+:H+ was maintained was consistent with a simple mass-action interaction for M-DNA formation. The differences between Zn(II) and Ni(II) M-DNA formation show that although it requires a higher pH or transition metal ion concentration, Ni(II) M-DNA is more stable than Zn(II) M-DNA once formed. This difference could play an important role in applications of M-DNA which required modulation in the stability of the M-DNA conformation. Surface Plasmon Resonance Fluorescence DNA-drug interactions DNA-metal ion interactions DNA conformation
323	Engineering Applications of Surface Plasmon Resonance: Protein–Protein and Protein–Molecule Interactions Ignagni, Nicholas January 2011 (has links) Protein-protein and protein-molecule interactions are complicated phenomena due to the tendency of proteins to change shape and function in response to their environment. Protein aggregation whether onto surfaces or in solution, can pose numerous problems in industry. Surface plasmon resonance (SPR) devices and quartz crystal microbalances (QCM) are two real-time, label free methods that can be used to detect the interactions between molecules on surfaces. These devices often employ self-assembled monolayers (SAMs) to produce specific surfaces for studying protein-protein interactions. The objective of this work was to develop methodologies utilizing SPR to better understand protein-protein and protein-molecule interactions with possible applications in the food and separation industrial sectors. A very well characterized whey protein, β-lactoglobulin (BLG), is used in numerous applications in the food industry. BLG can undergo different types of self-aggregation due changes in external environment factors such as buffer strength, pH or temperature. In this work, a hydrophilic SAM was developed and used to study the interaction and non-specific adsorption of BLG and palmitic acid (PA), a molecule which is known to bind to BLG. It was found that PA tended to reduce BLG conformational changes once on the surface, resulting in a decrease in its surface adhesion. Fluorescent excitation emission matrices (EEM’s) using a novel fluorescence probe technique were utilized to detect protein on the surface as well as conformational changes on the surface of the sensor, although the extent these changes could not be quantified. Another whey protein, α-lactoglobulin (AL), was utilized as a surrogate protein to study the adsorption of colloidal/particulate and protein matter (CPP) extracted from filtration studies of river water. A large fraction of natural organic matter (NOM), the major foulant in membrane based water filtration, is CPP and protein. Understanding the interactions between these components is essential in abating NOM membrane fouling. Several SPR methods were investigated in order to verify the interactions. A mixture of AL and CPP particles in solution prevented the non-specific adsorption of AL to the SAM surface. This change in association was then detected through SPR. Fluorescent EEM’s of the sensor surface verified that CPP and AL bound to the surface. This finding has fundamental significance in the interpretation of NOM-based membrane fouling. To better understand the mechanisms behind non-specific adsorption, a mechanistic mathematical model was developed to describe the adsorption of BLGs onto the hydrophilic SAM. The resulting model performed well in terms of predicting adsorption based on SPR data. The model incorporated the monomer-dimer equilibrium of BLG in solution, highlighting the impact of protein aggregation on non-specific adsorption mechanisms. For future studies, improvement in fluorescent FOP surface scan methodology would help identify different protein/molecules and conformations on the surface. Surface Plasmon Resonance SPR Adsorption protein Beta Lactoglobulin interactions kinetics membrane fouling Chemical Engineering
324	Amplification of Long-Range Surface Plasmon-Polaritons De Leon Arizpe, Israel 18 February 2011 (has links) Surface plasmon-polaritons are optical surface waves formed through the interaction of photons with free electrons at the surface of metals. They offer interesting applications in a broad range of scientific fields such as physics, chemistry, biology, and material science. However, many of such applications face limitations imposed by the high propagation losses of these waves at visible and near-infrared wavelengths, which result mainly from power dissipation in the metal. In principle, the propagation losses of surface plasmon-polaritons can be compensated through optical amplification. The objective of this thesis is to provide deeper insights on the physics of surface plasmon-polariton amplification and spontaneous emission in surface plasmon-polariton amplifiers through theoretical and experimental vehicles applied (but not necessarily restricted) to a particular plasmonic mode termed long-range surface plasmon-polariton. On the theoretical side, the objective is approached by developing a realistic theoretical model to describe the small-signal amplification of surface plasmon-polaritons in planar structures incorporating dipolar gain media such as organic dye molecules, rare-earth ions, and quantum dots. This model takes into account the inhomogeneous gain distribution formed near the metal surface due to a non-uniform excitation of dipoles and due to a position-dependent excited-state dipole lifetime that results from near-field interactions between the excited dipoles and the metal. Also, a theoretical model to describe the amplified spontaneous emission of surface plasmon-polaritons supported by planar metallic structures is developed. This model takes into account the different energy decay channels into which an exited dipole located in the vicinity of the metal can relax. The validity of this model is confirmed through experimentation. On the experimental side, the objective is approached by providing a direct experimental demonstration of complete loss compensation in a plasmonic waveguide. The experiments are conducted using the long-range surface plasmon-polariton supported by a symmetric thin gold waveguide incorporating optically pumped organic dye molecules in solution as the gain medium. Also, an experimental study of spontaneous emission in a long-range surface plasmon-polariton amplifier is presented. It is shown that this amplifier benefits from a low spontaneous emission into the amplified mode, which leads to an optical amplifier with low noise characteristics. The experimental setup and techniques are explained in detail. Surface plasmon-polaritons Optical amplification Amplified spontaneous emission Stimulated emission Optical waveguides
325	Plasmon hybridization in real metals January 2012 (has links) By treating free electrons in metallic nanostructures as incompressible and irrotational fluid, Plasmon hybridization (PH) method can be used as a very useful tool in interpolating the electric magnetic behaviors of complex metallic nanostructures. Using PH theory and Finite Element Method (FENI), we theoretically investigated the optical properties of some complex nanostructrus including coupled nanoparticle aggregates and nanowires. We investigated the plasmonic properties of a symmetric silver sphere heptamer and showed that the extinction spectrum exhibited a narrow Fano resonance. Using the plasmon hybridization approach and group theory we showed that this Fano resonance is caused by the interference of two bonding dipolar subradiant and superradiant plasmon modes of E1u symmetry. We investigate the effect of structural symmetry breaking and show that the energy and shape of the Fano resonance can be tuned over a broad wavelength range. We show that the wavelength of the Fano resonance depends very sensitively on the dielectric permittivity of the surrounding media. Besides heptamer, we also used plasmon hybridization method and finite element method to investigate the plasmonic properties of silver or gold nano spherical clusters. For symmetric clusters, we show how group theory can be used to identify the microscopic nature of the plasmon resonances. For larger clusters, we show that narrow Fano resonances are frequently present in their optical spectra. As an example of asymmetric clusters, we demonstrate that clusters of four identical spherical particles support strong Fano-like interference. This feature is highly sensitive to the polarization of the incident electric field due to orientation-dependent coupling between particles in the cluster. Nanowire plasmons can be launched by illumination at one terminus of the nanowire and emission can be detected at the other end of the wire. With PH theory we can predict how the polarization of the emitted light depends on the polarization of the incident light. Depending on termination shape, a nanowire can serve as either a polarization-maintaining waveguide, or as a polarization-rotating, nanoscale half-wave plate. We also investigated how the properties of a nearby substrate modify the excitation and propagation of plasmons in subwavelength silver wires. Applied sciences Pure sciences Plasmon hybridization Metals Metallic nanostructures Interpolating Condensed matter physics Nanotechnology
326	Single Particle Studies on the Influence of the Environment on the Plasmonic Properties of Single and Assembled Gold Nanoparticles of Various Shapes Swanglap, Pattanawit 16 September 2013 (has links) Plasmonic nanoparticles and their assembly have the potential to serve as a platform in practical applications such as photonics, sensing, and nano-medicine. To use plasmonic nanoparticles in these applications, it is important to understand their optical properties and find methods to control their optical response. Using polarization-sensitive dark-field spectroscopy to study self-assembled nanoparticle rings on substrates with different permittivities I show that the interaction between collective plasmon resonances and the substrate can control the spatial scattering image. Using liquid crystals as an active medium that can be controlled with an external electric field I show that the Fano resonance of an asymmetric plasmonic assembly can be actively controlled utilizing the polarization change of scattered light passing through the liquid crystal device. Furthermore, utilizing the strong electromagnetic field enhancement of coupled plasmonic “nanospikes” on the surface of gold nanoshells with a silica core, I show the use of single spiky nanoshells as surface-enhanced Raman spectroscopy substrates. Individual spiky nanoshells give surprisingly reproducible surface-enhanced Raman spectroscopy intensities with a low standard deviation compared to clusters of nanoparticles. In summary, the work presented here provides understanding of the plasmonic response for assembled nanoparticles on different substrates, illustrated a new method to actively control the optical response of plasmonic nanoparticles, and characterizes spiky nanoshells as surface-enhanced Raman scattering platform.
327	Hydrodynamic Modelling of the Electronic Response of Carbon Nanotubes Mowbray, Duncan John January 2007 (has links) The discovery of carbon nanotubes by Iijima in 1991 has created a torrent of new research activities. Research on carbon nanotubes ranges from studying their fundamental properties, such as their electron band structure and plasma frequencies, to developing new applications, such as self-assembled nano-circuits and field emission displays. Robust models are now needed to enable a better understanding of the electronic response of carbon nanotubes. We use time-dependent density functional theory to derive a two-fluid two-dimensional (2D) hydrodynamic model describing the collective response of a multiwalled carbon nanotube with dielectric media embedded inside or surrounding the nanotube. We study plasmon hybridization of the nanotube system in the UV range, the stopping force for ion channelling, the dynamical image potential for fast ions, channelled diclusters and point dipoles, and the energy loss for ions with oblique trajectories. Comparisons are made of results obtained from the 2D hydrodynamic model with those obtained from an extension of the 3D Kitagawa model to cylindrical geometries. carbon nanotubes hydrodynamic model plasmon excitations stopping force image potential self energy ion channelling Applied Mathematics
328	Biophysical investigation of M-DNA Wood, David Owen 31 May 2005 (has links) M-DNA is a complex formed between normal double-stranded DNA and the transition metal ions Zn2+, Ni2+, and Co2+ that is favoured by an alkaline pH. Previous studies have suggested that M-DNA formation involves replacement of the imino protons of G and T bases by the transition metal ions involved in forming the complex. Owing to the conductive properties of this unique DNA conformation, it has potential applications in nanotechnology and biosensing. This work was aimed at improving existing methods and developing new methods of characterizing M-DNA. The effects of base substitutions, particularly those of G and T, were evaluated in light of the proposed structure. Differences between M-DNA conformations induced by Zn2+ and Ni2+ were also investigated with a variety of techniques and compared to the effects of Cd2+ and Mg2+ on double-stranded DNA. M-DNA formation and stability were studied with an ethidium bromide (EtBr) based assay, M-DNA induced fluorescence quenching of DNA labelled with fluorescein and a compatible quenching molecule, isothermal titration calorimetry (ITC), and surface plasmon resonance (SPR). Production of monoclonal antibodies against the conformation was also attempted but was unsuccessful. The EtBr-based assay showed Ni(II) M-DNA to be much more stable than Zn(II) M-DNA as a function of pH and in the presence of ethylenediaminetetraacetic acid. Sequence-dependency and the effect of base substitutions were measured as a function of pH. With regards to sequence, d(G)nd(C)n tracts were found to form the conformation most easily. Base substitutions with G and T analogues that lowered the pKa of these bases were found to stabilize M-DNA more strongly than other base substitutions. A combination of temperature-dependant EtBr and ITC assays showed M-DNA formation to be endothermic, and therefore entropy driven. The SPR studies demonstrated many qualitative differences between Zn(II) and Ni(II) M-DNA formation, allowed characterization of Zn2+, Ni2+, Cd2+, and Mg2+ complexes with single-stranded DNA, and provided unambiguous evidence that M-DNA formation results in very little denaturation of double-stranded DNA. Specifically, the SPR study showed Ni(II) M-DNA to be more stable than Zn(II) M-DNA in the absence of transition metal ions, but also showed that Ni(II) M-DNA required higher concentrations of Ni2+ than Zn2+ to fully form the respective M-DNA conformations. Finally, quenching studies demonstrated Zn(II) M-DNA formation over a pH range from 6.5 to 8.5 provided that a Zn2+:H+ ratio of roughly 105 was maintained. The Keq for this interaction was 1.3 x 10-8 with 1.4 H+ being liberated per base bair of M-DNA formed. These results support the proposed structural model of M-DNA, as lowering the pKa of the bases having titratable protons over the pH range studied facilitated M-DNA formation. The fact that Zn(II) M-DNA formation was observed by fluorescence quenching at any pH provided that a constant ratio of Zn2+:H+ was maintained was consistent with a simple mass-action interaction for M-DNA formation. The differences between Zn(II) and Ni(II) M-DNA formation show that although it requires a higher pH or transition metal ion concentration, Ni(II) M-DNA is more stable than Zn(II) M-DNA once formed. This difference could play an important role in applications of M-DNA which required modulation in the stability of the M-DNA conformation. Surface Plasmon Resonance Fluorescence DNA-drug interactions DNA-metal ion interactions DNA conformation
329	SURFACE PLASMON COUPLED SENSOR AND NANOLENS Ko, Hyungduk 2009 May 1900 (has links) This dissertation consists of two topics. One is a "Multi-pass Fiber Optic Surface Plasmon Resonance Sensor (SPR)" and the other is a "Nano-metallic Surface Plasmon Lens." Since both topics involved surface plasmon, the title of this dissertation is named "Surface plasmon coupled sensor and nanolens." For a multi-pass fiber optic SPR sensor, a fiber optic 4-pass SPR sensor coupled with a field-assist capability for detecting an extremely low concentration of charged particles is first demonstrated. The multipass feature increases the sensitivity by a factor equal to the number of passes. The field-assist feature forces charged particles/molecules to the SPR surface, increasing the sensitivity by an additional factor of about 100. Overall, the sensitivity exceeds the one-pass SPR device by a factor of about 400. A 10 pM concentration of 47 nm diameter polystyrene (PS) latex beads and 1 ?M concentration of salt dissolved in DI water were detected within a few seconds by the combined system. The equivalent index resolution for atomic size corresponding to ionized chlorine in salt is 10-8. This technique offers the potential for sensitive and fast detection of biomolecules in a solution. Secondly, a 44-pass fiber optic surface plasmon resonance (SPR) sensor coupled with a field-assist capability for measurement of refractive index change due to positive and negative ions is shown. The field-assist feature forces ions to the SPR surface, causing the SPR signal response to change which reflects a decrease or increase in refractive index depending on whether positive or negative ions are being attracted to the surface. This technique offers the potential for the sensitive detection of cations and anions in a solution. For a nano-metallic surface plasmon lens, we analyze the transmission of a normally incident plane wave through an Ag/dielectric layered concentric ring structure using finite difference time domain (FDTD) analysis. The dependency of the transmission efficiency on the refractive index in slit is studied. The numerical analysis indicates that the focusing beyond diffraction limit is found even at the extended focal length comparable to the distance of 7" from the exit plane using a circularly polarized coherent plane wave, ?=405 nm. Especially, compared to an Ag-only structure, the Ag/ LiNbO3 structure amplifies the transmission power by a factor of 6. Therefore, this Ag/dielectric layered lens has the potential for significantly higher resolution imaging and optical data storage. surface plasmon resonance multi-pass SPR sensor fiber optic SPR sensor light transmission nano-optic lens
330	A Numerical Study On Dependent Absorption And Scattering By Interacting Nano-sized Particles Donmezer, Fatma Nazli 01 June 2009 (has links) (PDF) Understanding and manipulating nanosized particles is crucial for the advancement of nanotechnology research. Dependent light scattering of noble metals can be used to achieve new material responses that can be used in different applications. Dependent light scattering of nanoparticles allows the understanding of orientation and location of closely positioned particles. Besides, dependently scattering metallic particles create significantly enhanced near fields and high absorption rates when excited at their plasmon resonance. It is used for spectrally selective heating and melting of nanosized particles as a nanomanufacturing method. With numerical methods dependent scattering properties of particles can be obtained. In this study, the dependent optical absorption efficiencies of metallic nanoparticles are obtained with the newly developed Integrated Poynting Vector Approach (IPVA). This is used in conjunction with a numerical light scattering solution tool DDSCAT. Results indicate that IPVA and DDSCAT together can be used for the estimation of scattering and absorption of nanoparticles affected by the near field of other particles in their close vicinity. The method is suggested to be suitable for the understanding of physical mechanisms behind dependent scattering prior to experiments that require lots of effort and resources. TJ Mechanical Engineering. 1-1570

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