Global ETD Search

11	Optical Properties of Individual Nano-Sized Gold Particle Pairs: Mie-Scattering, Fluorescence, and Raman-Scattering Olk, Phillip 15 July 2008 (has links) This thesis examines and exploits the optical properties of pairs of MNPs. Pairs of MNPs offer two further parameters not existent at single MNPs, which both affect the local optical fields in their vicinity: the distance between them, and their relative orientation with respect to the polarisation of the excitation light. These properties are subject of three chapters: One section examines the distance-dependent and orientation-sensitive scattering cross section (SCS) of two equally sized MNPs. Both near- and far-field interactions affect the spectral position and spectral width of the SCS. Far-field coupling affects the SCS even in such a way that a two-particle system may show both a blue- and redshifted SCS, depending only on the distance between the two MNPs. The maximum distance for this effect is the coherence length of the illumination source – a fact of importance for SCS-based experiments using laser sources. Another part of this thesis examines the near-field between two MNPs and the dependence of the locally enhanced field on the relative particle orientation with respect to the polarisation of the excitation light. To attain a figure of merit, the intensity of fluorescence light from dye molecules in the surrounding medium was measured at various directions of polarisation. The field enhancement was turned into fluorescence enhancement, even providing a means for sensing the presence of very small MNPs of 12 nm in diameter. In order to quantify the near-field experimentally, a different technique is devised in a third section of this thesis – scanning particle-enhanced Raman microscopy (SPRM). This device comprises a scanning probe carrying an MNP which in turn is coated with a molecule of known Raman signature. By manoeuvring this outfit MNP into the vicinity of an illuminated second MNP and by measuring the Raman signal intensity, a spatial mapping of the field enhancement was possible. / Diese Dissertation untersucht und nutzt die optischen Eigenschaften von Paaren von Metall-Nanopartikeln (MNP). MNP-Paare bieten gegenüber einzelnen MNP zwei weitere Parameter, welche beide auf das optische Nahfeld der zwei MNPs wirken: zum Einen der Abstand der zwei MNPs zueinander, zum Anderen die relative Ausrichtung des Paares bezüglich der Polarisation des anregenden Lichts. Diese Eigenschaften sind Thema der Arbeit: Ein Abschnitt untersucht den abstands- und orientierungsabhängigen Streuquerschnitt (SQS) zweier gleichgroßer MNPs. Die spektrale Position und die Breite des SQS wird von Wechselwirkungen sowohl im Nah- als auch im Fernfeld beeinflusst. Der Einfluß der Fernfeld-Wechselwirkung geht so weit, daß ein Zwei-MNP-System sowohl einen blau- als auch einen rotverschobenen SQS haben kann – dies hängt lediglich vom Abstand der zwei MNPs ab. Die Reichweite dieser Fernfeld-Wechselwirkung wird durch die Kohärenzlänge der Beleuchtungsquelle bestimmt – eine wichtige Tatsache für SQS-Untersuchungen, welche Laserquellen verwenden. Ein weiterer Teil der Dissertation untersucht das Nahfeld zwischen zwei MNPs. Insbesondere wird dargestellt, inwieweit die Überhöhung des Nahfelds von der Orientierung des Partikelpaares bezüglich der Polarisation des Anregungslichts abhängt. Um den Effekt quantifizieren zu können, wurde die Intensität der Fluoreszenz des umgebenden Mediums für verschiedene Polarisationsrichtungen gemessen. Die lokale Feldverstärkung konnte in eine Fluoreszenzverstärkung gewandelt werden, mit deren Hilfe sich sogar die Anwesenheit sehr kleiner MNPs von nur 12 nm Durchmesser nachweisen ließ. Wie Nahfeld-Intensitäten experimentell quantifiziert werden können, stellt ein dritter Abschnitt dieser Dissertation vor – per MNP-verstärkter Raman-Rastersonden-Mikroskopie. Diese Technik besteht aus einer Rastersonde, welcher ein MNP anheftet, welches wiederum mit einem Molekül bekannter Ramansignatur überzogen ist. Indem solch eine Sonde in die unmittelbare Nähe eines zweiten, beleuchteten MNPs gebracht wurde und dabei die Intensität des Raman-Signals aufgezeichnet wurde, ließ sich die räumliche Verteilung der Ramanverstärkung vermessen. info:eu-repo/classification/ddc/530 ddc:530
12	Nanoscale light-matter interactions in the near-field of high-Q microresonators Eftekhar, Ali Asghar 10 November 2011 (has links) The light-matter interaction in the near-field of high-Q resonators in SOI and SiN platforms is studied. The interactions of high-Q traveling-wave resonators with both resonant and non-resonant nanoparticles are studied and different applications based on this enhanced interactions in near-field such as high-resolution imaging of mode profile of high-Q resonators, label-free sensing, optical trapping, and SERS sensing are investigated. A near-field imaging system for the investigation of the near-field phenomena in the near-field of high-Q resonators is realized. A new technique for high-resolution imaging of the optical modes in high-Q resonators based on the near-field perturbation is developed that enables to achieve a very high resolution (< 10 nm) near-field image. The prospect of the high Q resonators on SOI platform for highly multiplexed label-free sensing and the effect of different phenomena such as the analyte drift and diffusion and the binding kinetics are studied. Also, the possibility of enhancing nanoparticle binding to the sensor surface using optical trapping is investigated and the dynamic of a nanoparticle in the high-Q resonator optical trap is studied. Furthermore, the interaction between a resonant nanoparticle with a high-Q microdisk resonator and its application for SERS sensing is studied. A model for interaction of resonant nanoparticles with high-Q resonators is developed and the optimal parameters for the design of coupled microdisk resonator and a plasmonic nanoparticle are calculated. The possible of resonant plasmonic nanoparticle trapping and alignment in an SiN microdisk resonator optical trap is also shown. Label-free sensing SERS High Q resonator Field enhancement Resonator-enhanced-SERS Optical trapping Near-field interactions Near-field imaging Optical amplifiers Nonlinear optics Near-field microscopy Scanning electron microscopy
13	Theoretical and numerical investigation of plasmon nanofocusing in metallic tapered rods and grooves Vogel, Michael Werner January 2009 (has links) Effective focusing of electromagnetic (EM) energy to nanoscale regions is one of the major challenges in nano-photonics and plasmonics. The strong localization of the optical energy into regions much smaller than allowed by the diffraction limit, also called nanofocusing, offers promising applications in nano-sensor technology, nanofabrication, near-field optics or spectroscopy. One of the most promising solutions to the problem of efficient nanofocusing is related to surface plasmon propagation in metallic structures. Metallic tapered rods, commonly used as probes in near field microscopy and spectroscopy, are of a particular interest. They can provide very strong EM field enhancement at the tip due to surface plasmons (SP’s) propagating towards the tip of the tapered metal rod. A large number of studies have been devoted to the manufacturing process of tapered rods or tapered fibers coated by a metal film. On the other hand, structures such as metallic V-grooves or metal wedges can also provide strong electric field enhancements but manufacturing of these structures is still a challenge. It has been shown, however, that the attainable electric field enhancement at the apex in the V-groove is higher than at the tip of a metal tapered rod when the dissipation level in the metal is strong. Metallic V-grooves also have very promising characteristics as plasmonic waveguides. This thesis will present a thorough theoretical and numerical investigation of nanofocusing during plasmon propagation along a metal tapered rod and into a metallic V-groove. Optimal structural parameters including optimal taper angle, taper length and shape of the taper are determined in order to achieve maximum field enhancement factors at the tip of the nanofocusing structure. An analytical investigation of plasmon nanofocusing by metal tapered rods is carried out by means of the geometric optics approximation (GOA), which is also called adiabatic nanofocusing. However, GOA is applicable only for analysing tapered structures with small taper angles and without considering a terminating tip structure in order to neglect reflections. Rigorous numerical methods are employed for analysing non-adiabatic nanofocusing, by tapered rod and V-grooves with larger taper angles and with a rounded tip. These structures cannot be studied by analytical methods due to the presence of reflected waves from the taper section, the tip and also from (artificial) computational boundaries. A new method is introduced to combine the advantages of GOA and rigorous numerical methods in order to reduce significantly the use of computational resources and yet achieve accurate results for the analysis of large tapered structures, within reasonable calculation time. Detailed comparison between GOA and rigorous numerical methods will be carried out in order to find the critical taper angle of the tapered structures at which GOA is still applicable. It will be demonstrated that optimal taper angles, at which maximum field enhancements occur, coincide with the critical angles, at which GOA is still applicable. It will be shown that the applicability of GOA can be substantially expanded to include structures which could be analysed previously by numerical methods only. The influence of the rounded tip, the taper angle and the role of dissipation onto the plasmon field distribution along the tapered rod and near the tip will be analysed analytically and numerically in detail. It will be demonstrated that electric field enhancement factors of up to ~ 2500 within nanoscale regions are predicted. These are sufficient, for instance, to detect single molecules using surface enhanced Raman spectroscopy (SERS) with the tip of a tapered rod, an approach also known as tip enhanced Raman spectroscopy or TERS. The results obtained in this project will be important for applications for which strong local field enhancement factors are crucial for the performance of devices such as near field microscopes or spectroscopy. The optimal design of nanofocusing structures, at which the delivery of electromagnetic energy to the nanometer region is most efficient, will lead to new applications in near field sensors, near field measuring technology, or generation of nanometer sized energy sources. This includes: applications in tip enhanced Raman spectroscopy (TERS); manipulation of nanoparticles and molecules; efficient coupling of optical energy into and out of plasmonic circuits; second harmonic generation in non-linear optics; or delivery of energy to quantum dots, for instance, for quantum computations.
14	The substrate matters in the Raman spectroscopy analysis of cells Mikoliunaite, Lina, Rodriguez, Raul D., Sheremet, Evgeniya, Kolchuzhin, Vladimir, Mehner, Jan, Ramanavicius , Arunas, Zahn, Dietrich R.T. 11 November 2015 (has links) (PDF) Raman spectroscopy is a powerful analytical method that allows deposited and/or immobilized cells to be evaluated without complex sample preparation or labeling. However, a main limitation of Raman spectroscopy in cell analysis is the extremely weak Raman intensity that results in low signal to noise ratios. Therefore, it is important to seize any opportunity that increases the intensity of the Raman signal and to understand whether and how the signal enhancement changes with respect to the substrate used. Our experimental results show clear differences in the spectroscopic response from cells on different surfaces. This result is partly due to the difference in spatial distribution of electric field at the substrate/cell interface as shown by numerical simulations. We found that the substrate also changes the spatial location of maximum field enhancement around the cells. Moreover, beyond conventional flat surfaces, we introduce an efficient nanostructured silver substrate that largely enhances the Raman signal intensity from a single yeast cell. This work contributes to the field of vibrational spectroscopy analysis by providing a fresh look at the significance of the substrate for Raman investigations in cell research. Hefepilze Raman-Spektroskopie Spitzenverstärkte Raman-Spektroskopie Finite-Elemente-Methode Technische Universität Chemnitz Publikationsfonds yeast cells Raman spectroscopy Surface-enhanced Raman spectroscopy Tip-enhanced Raman spectroscopy Electromagnetic field enhancement Finite element simulations Technische Universität Chemnitz Publication funds ddc:530 ddc:535 ddc:579 Hefeartige Pilze Optische Spektroskopie
15	Surface- and tip-enhanced Raman spectroscopy reveals spin-waves in iron oxide nanoparticles Rodriguez, Raul D., Sheremet, Evgeniya, Deckert-Gaudig, Tanja, Chaneac, Corinne, Hietschold, Michael, Deckert, Volker, Zahn, Dietrich R. T. 03 June 2015 (has links) (PDF) Nanomaterials have the remarkable characteristic of displaying physical properties different from their bulk counterparts. An additional degree of complexity and functionality arises when oxide nanoparticles interact with metallic nanostructures. In this context the Raman spectra due to plasmonic enhancement of iron oxide nanocrystals are here reported showing the activation of spin-waves. Iron oxide nanoparticles on gold and silver tips are found to display a band around 1584 cm−1 attributed to a spin-wave magnon mode. This magnon mode is not observed for nanoparticles deposited on silicon (111) or on glass substrates. Metal–nanoparticle interaction and the strongly localized electromagnetic field contribute to the appearance of this mode. The localized excitation that generates this mode is confirmed by tip-enhanced Raman spectroscopy (TERS). The appearance of the spin-waves only when the TERS tip is in close proximity to a nanocrystal edge suggests that the coupling of a localized plasmon with spin-waves arises due to broken symmetry at the nanoparticle border and the additional electric field confinement. Beyond phonon confinement effects previously reported in similar systems, this work offers significant insights on the plasmon-assisted generation and detection of spin-waves optically induced. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. Alpha-Fe2O3 Nanopartikel Raman-Spektroskopie Spitzenverstärkte Raman-Spektroskopie Spinwelle Technische Universität Chemnitz Allianzlizenz alpha-Fe2O3 nanoparticles Raman spectroscopy Tip-enhanced Raman spectroscopy Electromagnetic field enhancement Magnon mode ddc:530 ddc:534 ddc:535 ddc:538 ddc:539 Spinwelle Eisenerz Optische Spektroskopie
16	Dielektrische Wellenleitergitter in Resonanz / Theorie, Charakterisierung und Anwendung / All-dielectric Resonant Waveguide Gratings / Theory, Characterization and Application Selle, André 19 November 2008 (has links) No description available. 530 Physik Mathematics and Computer Science Wellenleitergitter Doppel-Gitter-Wellenleiter-Struktur evaneszente Felderhöhung Fluoreszenz elektromagnetische Resonanz Resonant waveguide grating double grating waveguide structure evanescent field enhancement fluorescence electromagnetic resonance 33.05 33.18 RPV 210: Optische Wellenleiter {Physik} RPV 220: Spiegel {Physik: Optik} RPV 340: Filter {Physik: Optik}
17	Light-induced electron dynamics in and around metallic nanostructures Wegner, Gino 11 July 2024 (has links) Gegenstand der Untersuchungen dieser Arbeit ist die analytische und numerische Studie der plasmonischen Eigenschaften vorhanden in Silbernanodrähten von verschiedener horizontaler Geometrie aufgrund verschiedener Modelle der optischen Antwort der Leitungselektronen. Nach einer hierarchischen Anordnung von linearen Volumen-Materialmodellen, welche innerhalb der plasmonischen Literatur genutzt werden, untersuchen wir die Verwicklung von (nicht)lokaler und dispersiver Antwort mit geometrischen Parametern von Monomeren und Dimeren. Unsere analytischen Studien fokussieren sich auf einzelne zylindrische Drähte, wobei wir das Auftreten von Radius-abhängiger Dämpfung in lokalisierten Oberflächenplasmonen nachweisen, ähnlich dem Konzept der begrenzten mittleren freien Weglänge diskutiert von Kreibig und Mitarbeitern. Weiterhin wird ein Streuproblem mit transversaler Nichtlokalität und "No-slip"- Randbedingung gelöst, gefolgt von einer Diskussion einer Randbedingung, welche zwischen “No-Slip”- und “Slip”-Bedinung interpoliert. Aus numerischer Sicht wird die Streuung an abgerundeten und gleichseitigen dreieckigen und Bowtie-Drähten behandelt mit Fokus auf einer vollanalytischen Beschreibung der Eckenrundung mittels Bézier- Kurven. Dies enthüllt den Krümmungsradius als neuen geometrischen Parameter. Das Variieren der Lückenbreite und Eckenrundung führt zu Verstärkungsfaktoren, welche relevant für oberflächenverstärkte Raman-Streuung einzelner Moleküle sind, in ausgezeichneten räumlichen Bereichen abhängig von der Art der Resonanz. Innerhalb der Extinktionsspektren von dreieckigen und Bowtie-Drähten erscheint eine Sequenz von nichtlokalen Maxima. Diese Sequenz ist am sensitivsten in Bezug auf die Änderung der Krümmung. Die Identifikation der (Hybrid-)Resonanzen basiert auf simulierten Ladungsdichteverteilungen. / Subject of this thesis is the analytical and numerical study of the plasmonic properties present in silver nanowires of different horizontal geometries due to different models of optical response of conduction electrons. Following a hierarchical arrangement of linear bulk material models, used throughout the plasmonic literature, we investigate the intertwining of (non)local and dispersive response with geometrical parameters of monomers and dimers. Our analytical studies focus on single cylindrical wires, revealing the occurrence of radius-dependent damping of localized surface plasmons similar to the concept of limited-mean-free-path discussed by Kreibig and coworkers. Further, a scattering problem with transverse nonlocality and s no-slip condition is solved followed by a discussion of a boundary condition interpolating between the slip and no-slip conditions. On a numerical level, the scattering by rounded and equilateral triangular and bowtie nanowires is treated based on a full analytical description of the corner rounding via Bézier curves revealing the radius of curvature as a new geometrical degree of freedom. Tuning of gap size and corner rounding reveals enhancement factors relevant for surface-enhanced Raman scattering of single molecules in distinguished spatial domains dependent on the type of resonance. Within the extinction spectra a nonlocal peak sequence emerges. This sequence is most sensitive to curvature variations and arises in the triangular monomer and bowtie dimer. The identification of (hybrid) resonances is based on charge density simulations. Licht-Materie-Wechselwirkung Metalle Plasmonik Nanoplasmonik Materialmodell Nichtlokalität Dispersion Lokalisierte Oberflächenplasmonen SERS Feldverstärkung Extinktion Kontinuum Randbedingungen Herstellungsmängel Oberflächenrauigkeit light-matter interaction metals plasmonics nano plasmonics material models nonlocality dispersion localized surface plasmons SERS field enhancement extinction continuum boundary conditions fabrication imperfection surface roughness nanoplasmonics 530 Physik ddc:530
18	Ordnungs-/Unordnungsphänomene in korrelierten Perowskitschichten anhand von fortgeschrittener Raman-Spektroskopie / Ordering/Disordering phenomena in correlated perovskite films on the basis of advanced Raman spectroscopy Meyer, Christoph 18 July 2018 (has links) No description available. 530 Physik (PPN621336750)
19	Surface- and tip-enhanced Raman spectroscopy reveals spin-waves in iron oxide nanoparticles Rodriguez, Raul D., Sheremet, Evgeniya, Deckert-Gaudig, Tanja, Chaneac, Corinne, Hietschold, Michael, Deckert, Volker, Zahn, Dietrich R. T. 03 June 2015 (has links) Nanomaterials have the remarkable characteristic of displaying physical properties different from their bulk counterparts. An additional degree of complexity and functionality arises when oxide nanoparticles interact with metallic nanostructures. In this context the Raman spectra due to plasmonic enhancement of iron oxide nanocrystals are here reported showing the activation of spin-waves. Iron oxide nanoparticles on gold and silver tips are found to display a band around 1584 cm−1 attributed to a spin-wave magnon mode. This magnon mode is not observed for nanoparticles deposited on silicon (111) or on glass substrates. Metal–nanoparticle interaction and the strongly localized electromagnetic field contribute to the appearance of this mode. The localized excitation that generates this mode is confirmed by tip-enhanced Raman spectroscopy (TERS). The appearance of the spin-waves only when the TERS tip is in close proximity to a nanocrystal edge suggests that the coupling of a localized plasmon with spin-waves arises due to broken symmetry at the nanoparticle border and the additional electric field confinement. Beyond phonon confinement effects previously reported in similar systems, this work offers significant insights on the plasmon-assisted generation and detection of spin-waves optically induced. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. info:eu-repo/classification/ddc/530 ddc:530 info:eu-repo/classification/ddc/534 ddc:534 info:eu-repo/classification/ddc/535 ddc:535 info:eu-repo/classification/ddc/538 ddc:538 info:eu-repo/classification/ddc/539 ddc:539
20	The substrate matters in the Raman spectroscopy analysis of cells Mikoliunaite, Lina, Rodriguez, Raul D., Sheremet, Evgeniya, Kolchuzhin, Vladimir, Mehner, Jan, Ramanavicius, Arunas, Zahn, Dietrich R.T. 11 November 2015 (has links) Raman spectroscopy is a powerful analytical method that allows deposited and/or immobilized cells to be evaluated without complex sample preparation or labeling. However, a main limitation of Raman spectroscopy in cell analysis is the extremely weak Raman intensity that results in low signal to noise ratios. Therefore, it is important to seize any opportunity that increases the intensity of the Raman signal and to understand whether and how the signal enhancement changes with respect to the substrate used. Our experimental results show clear differences in the spectroscopic response from cells on different surfaces. This result is partly due to the difference in spatial distribution of electric field at the substrate/cell interface as shown by numerical simulations. We found that the substrate also changes the spatial location of maximum field enhancement around the cells. Moreover, beyond conventional flat surfaces, we introduce an efficient nanostructured silver substrate that largely enhances the Raman signal intensity from a single yeast cell. This work contributes to the field of vibrational spectroscopy analysis by providing a fresh look at the significance of the substrate for Raman investigations in cell research. info:eu-repo/classification/ddc/530 ddc:530 info:eu-repo/classification/ddc/535 ddc:535 info:eu-repo/classification/ddc/579 ddc:579 Hefeartige Pilze; Optische Spektroskopie

Search results