Abstract:
When noble metals particles are synthesized with progressively smaller dimensions, strikingly novel optical properties arise. For nanoscale particles, collective disturbances of the electron density known as localized surface plasmons resonances can arise, and these resonances are utilized in a variety of applications ranging from surface-enhanced molecular spectroscopy and sensing to photothermal cancer therapy to plasmon-driven photochemistry. Central to all of these studies is the plasmon’s remarkable ability to process light, capturing and converting it into intense near fields, heat, and even energetic carriers at the nanoscale. In the past decade, we have witnessed major advances in plasmonics which is directly linked with the much broader field of (colloidal) nanotechnology. These breakthroughs span from plasmon lasing and waveguides, plasmonic photochemistry and solar cells to active plasmonics, plasmonics nanocomposites and semiconductor plasmons.
All the above-mentioned phenomena rely on precise spatial placement and distinct control over the dimensions and orientation of the individual plasmonic building blocks within complex one-, two- or three-dimensional complex arrangements. For the nanofabrication of metal nanostructures at surfaces, most often lithographic approaches, e.g. e-beam lithography or ion-beam milling are generally applied, due to their versatility and precision. However, these techniques come along with several drawbacks such as limited scalability, limited resolution, limited compatibility with silicon manufacturing techniques, damping effects due to the polycrystalline nature of the metal nanostructures and low sample throughput. Thus, there is a great demand for alternative approaches for the fabrication of metal nanostructures to overcome the above-mentioned limitations. But why colloids? True three-dimensionality, lower damping, high quality modes due to mono-dispersity, and the absence of grain boundaries make the colloidal assembly an especially competitive method for high quality large-scale fabrication. On top of that, colloids provide a versatile platform in terms of size, shape, composition and surface modification and dispersion media.
540The combination of directed self-assembly and laser interference lithography is a versatile admixture of bottom-up and top-down approaches that represents a compelling alternative to commonly used nanofabrication methods. The objective of this thesis is to focus on large area fabrication of emergent spectroscopic properties with high structural and optical quality via colloidal self-assembly. We focus on synergy between optical and plasmonic effects such as: (i) coupling between localized surface plasmon resonance and Bragg diffraction leading to surface lattice resonance; (ii) strong light matter interaction between guided mode resonance and collective plasmonic chain modes leading to hybrid guided plasmon modes, which can further be used to boost the hot-electron efficiency in a semiconducting material; (iii) similarly, bilayer nanoparticle chains leading to chiro-optical effects. Following this scope, this thesis introduces a real-time tuning of such exclusive plasmonic-photonic (hybrid) modes via flexible template fabrication. Mechanical stimuli such as tensile strain facilitate the dynamic tuning of surface lattice resonance and chiro-optical effects respectively. This expands the scope to curb the rigidity in optical systems and ease the integration of such systems with flexible electronics or circuits.:Contents
Abstract
Kurzfassung
Abbreviations
1. Introduction and scope of the thesis
1.1. Introduction
1.1.1. Classical optics concepts
1.1.2. Top down fabrication methods and their challenges
1.1.3. Template-assisted self-assembly
1.1.4. Functional colloidal surface assemblies
1.2. Scope of the thesis
2. Results and Discussion
2.1. Mechanotunable Surface Lattice Resonances in the Visible Optical Range by Soft Lithography Templates and Directed Self-Assembly
2.1.1. Fabrication of flexible 2D plasmonic lattice
2.1.2. Investigation of the influence of particle size distribution on SLR quality
2.1.3. Band diagram analysis of 2D plasmonic lattice
2.1.4. Strain induced tuning of SLR
2.1.5. SEM and force transfer analysis in 2D plasmonic lattice under various strain
2.2. Hybridized Guided-Mode Resonances via Colloidal Plasmonic Self-Assembled Grating
2.2.1. Fabrication of hybrid opto-plasmonic structure via template assisted self-assembly
2.2.2. Comparison of optical band diagram of three (plasmonic, photonic and hybrid) different structures in TE and TM modes
2.2.3. Simulative comparison of optical properties of hybrid opto-plasmonic NP chains with a grating of metallic gold bars
2.2.4. Effect of cover index variation with water as a cover medium
2.3. Hot electron generation via guided hybrid modes
2.3.1. Fabrication of the hybrid GMR structure via LIL and lift-off process
2.3.2. Spectroscopic and simulative analysis of hybrid opto-plasmonic structures of different periodicities
2.3.3. Comparative study of photocurrent generation in different plasmonic structures
2.3.4. Polarization dependent response at higher wavelength
2.3.5. Directed self-assembly of gold nanoparticles within grating channels of a dielectric GMR structure supported by titanium dioxide film
2.4. Active Chiral Plasmonics Based on Geometrical Reconfiguration
2.4.1. Chiral 3D assemblies by macroscopic stacking of achiral chain substrates
3. Conclusion
4. Zusammenfassung
5. Bibliography
6. Appendix
6.1. laser interference lithography
6.2. Soft molding
6.3. Determine fill factor of plasmonic lattice
6.4. 2D plasmonic lattice of Au_BSA under strain
6.5. Characterizing order inside a 2D lattice
6.6. Template-assisted colloidal self-assembly
6.7. Out of plane lattice resonance in 1D and 2D lattices
6.8. E-Field distribution at out of plane SLR mode for 1D lattices of various periodicity with AOI 20°
6.9. Refractive index of PDMS and UV-PDMS
6.10. Refractive index measurement for sensing
6.11. Optical constants of TiO2, ma-N 405 photoresist and glass substrate measured from spectroscopic ellipsometry
Acknowledgement/ Danksagung
Erklärung & Versicherung
List of Publication
