@phdthesis{Pres2024,
  author    = {Pres, Sebastian},
  title     = {Detection of a plasmon-polariton quantum wave packet by coherent 2D nanoscopy},
  doi       = {10.25972/OPUS-34824},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-348242},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2024},
  abstract  = {Plasmonic nanostructures are considered promising candidates for essential components of integrated quantum technologies because of their ability to efficiently localize broad-band electromagnetic fields on the nanoscale. The resulting local near field can be understood as a spatial superposition of spectrally different plasmon-polariton modes due to the spectrally broad optical excitation, and thus can be described as a classical wave packet. Since plasmon polaritons, in turn, can transmit and receive non-classical light states, the exciting question arises to what extent they have to be described as quantum mechanical wave packets, i.e. as a superposition of different quantum states. But how to probe, characterize and eventually manipulate the quantum state of such plasmon polaritons? Up to now, probing at room temperatures relied completely on analyzing quantum optical properties of the corresponding in-going and out-going far-field photon modes. However, these methods so far only allow a rather indirect investigation of the plasmon-polariton quantum state by means of transfer into photons. Moreover, these indirect methods lack spatial resolution and therefore do not provide on-site access to the plasmon-polariton quantum state. However, since the spectroscopic method of coherent two-dimensional (2D) nanoscopy offers the capability to follow the plasmon- polariton quantum state both in Hilbert space and in space and time domain a complete characterization of the plasmon polariton is possible. In this thesis a versatile coherent 2D nanoscopy setup is presented combining spectral tunability and femtosecond time resolution with spatial resolution on the nanometer scale due to the detection of optically excited nonlinear emitted electrons via photoemission electron microscopy (PEEM). Optical excitation by amplitude- and phase-shaped, systematically-modified and interferometric-stable multipulse sequences is realized, and characterized via Fourier-transform spectral interferometry (FTSI). This linear technique enables efficient data acquisition in parallel to a simultaneously performed experiment. The full electric-field reconstruction of every generated multipulse sequence is used to analyze the effect of non-ideal pulse sequences on the two-dimensional spectral data of population-based multidimensional spectroscopy methods like, e.g., the coherent 2D nanoscopy applied in this thesis. Investigation of the spatially-resolved nonlinear electron emission yield from plasmonic gold nanoresonators by coherent 2D nanoscopy requires a quasi-particle treatment of the addressed plasmon-polariton mode and development of a quantum model to adequately describe the plasmon-assisted multi-quantum electron emission from nanostructures. Good agreement between simulated and experimental data enables to connect certain spectral features to superpositions of non-adjacent plasmon-polariton quantum states, i.e, non-adjacent occupation-number states of the underlying quantized, harmonic oscillator, thus direct probing of the plasmon-polariton quantum wave packet at the location of the nanostructure. This is a necessary step to locally control and manipulate the plasmon-polariton quantum state and thus of general interest for the realization of nanoscale quantum optical devices.},
  subject      = {Coherent Multidimensional Spectroscopy},
  language  = {en}
}
@phdthesis{Grimm2023,
  author    = {Grimm, Philipp Martin},
  title     = {Locally driven complex plasmonic nanoantenna systems},
  doi       = {10.25972/OPUS-30315},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-303152},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2023},
  abstract  = {Metallic nanostructures possess the ability to support resonances in the visible wavelength regime which are related to localized surface plasmons. These create highly enhanced electric fields in the immediate vicinity of metal surfaces. Nanoparticles with dipolar resonance also radiate efficiently into the far-field and hence serve as antennas for light. Such optical antennas have been explored during the last two decades, however, mainly as standalone units illuminated by external laser beams and more recently as electrically driven point sources, yet merely with basic antenna properties. This work advances the state of the art of locally driven optical antenna systems. As a first instance, the electric driving scheme including inelastic electron tunneling over a nanometer gap is merged with Yagi-Uda theory. The resulting antenna system consists of a suitably wired feed antenna, incorporating a tunnel junction, as well as several nearby parasitic elements whose geometry is optimized using analytical and numerical methods. Experimental evidence of unprecedented directionality of light emission from a nanoantenna is provided. Parallels in the performance between radiofrequency and optical Yagi-Uda arrays are drawn. Secondly, a pair of electrically connected antennas with dissimilar resonances is harnessed as electrodes in an organic light emitting nanodiode prototype. The organic material zinc phthalocyanine, exhibiting asymmetric injection barriers for electrons and holes, in conjunction with the electrode resonances, allows switching and controlling the emitted peak wavelength and directionality as the polarity of the applied voltage is inverted. In a final study, the near-field based transmission-line driving of rod antenna systems is thoroughly explored. Perfect impedance matching, corresponding to zero back-reflection, is achieved when the antenna acts as a generalized coherent perfect absorber at a specific frequency. It thus collects all guided, surface-plasmon mediated input power and transduces it to other nonradiative and radiative dissipation channels. The coherent interplay of losses and interference effects turns out to be of paramount importance for this delicate scenario, which is systematically obtained for various antenna resonances. By means of the here developed semi-analytical toolbox, even more complex nanorod chains, supporting topologically nontrivial localized edge states, are studied. The results presented in this work facilitate the design of complex locally driven antenna systems for optical wireless on-chip communication, subwavelength pixels, and loss-compensated integrated plasmonic nanocircuitry which extends to the realm of topological plasmonics.},
  subject      = {Plasmonik},
  language  = {en}
}
@phdthesis{Heinrich2022,
  author    = {Heinrich, Robert},
  title     = {Multi-species gas detection based on an external-cavity quantum cascade laser spectrometer in the mid-infrared fingerprint region},
  doi       = {10.25972/OPUS-26864},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-268640},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2022},
  abstract  = {Laser spectroscopic gas sensing has been applied for decades for several applications as atmospheric monitoring, industrial combustion gas analysis or fundamental research. The availability of new laser sources in the mid-infrared opens the spectral fingerprint range to the technology where multiple molecules possess their fundamental ro-vibrational absorption features that allow very sensitive detection and accurate discrimination of the species. The increasing maturity of quantum cascade lasers that cover this highly interesting spectral range motivated this research to gain fundamental knowledge about the spectra of hydrocarbon gases in pure composition and in complex mixtures as they occur in the petro-chemical industry. The long-term target of developing accurate and fast hydrocarbon gas analyzers, capable of real-time operation while enabling feedback-loops, would lead to a paradigm change in this industry. This thesis aims to contribute to a higher accuracy and more comprehensive understanding of the sensing of hydrocarbon gas mixtures. This includes the acquisition of yet unavailable high resolution and high accuracy reference spectra of the respective gases, the investigation of their spectral behavior in mixtures due to collisional broadening of their transitions and the verification of the feasibility to quantitatively discriminate the spectra when several overlapping species are simultaneously measured in gas mixtures. To achieve this knowledge a new laboratory environment was planned and built up to allow for the supply of the individual gases and their arbitrary mixing. The main element was the development of a broadly tunable external-cavity quantum cascade laser based spectrometer to record the required spectra. This also included the development of a new measurement method to obtain highly resolved and nearly gap-less spectral coverage as well as a sophisticated signal post-processing that was crucial to achieve the high accuracy of the measurements. The spectroscopic setup was used for a thorough investigation of the spectra of the first seven alkanes as of their mixtures. Measurements were realized that achieved a spectral resolution of 0.001 cm-1 in the range of 6-11 µm while ensuring an accuracy of 0.001 cm-1 of the spectra and attaining a transmission sensitivity of 2.5 x 10-4 for long-time averaging of the acquired spectra. These spectral measurements accomplish a quality that compares to state-of-the art spectral databases and revealed so far undocumented details of several of the investigated gases that have not been measured with this high resolution before at the chosen measurement conditions. The results demonstrate the first laser spectroscopic discrimination of a seven component gas mixture with absolute accuracies below 0.5 vol.\% in the mid-infrared provided that a sufficiently broad spectral range is covered in the measurements. Remaining challenges for obtaining improved spectral models of the gases and limitations of the measurement accuracy and technology are discussed.},
  subject      = {Quantenkaskadenlaser},
  language  = {en}
}
@phdthesis{Ochs2022,
  author    = {Ochs, Maximilian Thomas},
  title     = {Electrically Connected Nano-Optical Systems: From Refined Nanoscale Geometries to Selective Molecular Assembly},
  doi       = {10.25972/OPUS-29114},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-291140},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2022},
  abstract  = {Metallic nano-optical systems allow to confine and guide light at the nanoscale, a fascinating ability which has motivated a wide range of fundamental as well as applied research over the last two decades. While optical antennas provide a link between visible radiation and localized energy, plasmonic waveguides route light in predefined pathways. So far, however, most experimental demonstrations are limited to purely optical excitations, i.e. isolated structures are illuminated by external lasers. Driving such systems electrically and generating light at the nanoscale, would greatly reduce the device footprint and pave the road for integrated optical nanocircuitry. Yet, the light emission mechanism as well as connecting delicate nanostructures to external electrodes pose key challenges and require sophisticated fabrication techniques. This work presents various electrically connected nano-optical systems and outlines a comprehensive production line, thus significantly advancing the state of the art. Importantly, the electrical connection is not just used to generate light, but also offers new strategies for device assembly. In a first example, nanoelectrodes are selectively functionalized with self-assembled monolayers by charging a specific electrode. This allows to tailor the surface properties of nanoscale objects, introducing an additional degree of freedom to the development of metal-organic nanodevices. In addition, the electrical connection enables the bottom-up fabrication of tunnel junctions by feedback-controlled dielectrophoresis. The resulting tunnel barriers are then used to generate light in different nano-optical systems via inelastic electron tunneling. Two structures are discussed in particular: optical Yagi-Uda antennas and plasmonic waveguides. Their refined geometries, accurately fabricated via focused ion beam milling of single-crystalline gold platelets, determine the properties of the emitted light. It is shown experimentally, that Yagi-Uda antennas radiate light in a specific direction with unprecedented directionality, while plasmonic waveguides allow to switch between the excitation of two propagating modes with orthogonal near-field symmetry. The presented devices nicely demonstrate the potential of electrically connected nano-optical systems, and the fabrication scheme including dielectrophoresis as well as site-selective functionalization will inspire more research in the field of nano-optoelectronics. In this context, different future experiments are discussed, ranging from the control of molecular machinery to optical antenna communication.},
  subject      = {Nanooptik},
  language  = {en}
}
@phdthesis{Metzger2021,
  author    = {Metzger, Christian Thomas Peter},
  title     = {Development of photoemission spectroscopy techniques for the determination of the electronic and geometric structure of organic adsorbates},
  doi       = {10.25972/OPUS-22952},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-229525},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {The projects presented in this thesis cover the examination of the electronic and structural properties of organic thin films at noble metal-organic interfaces. Angle-resolved photoemission spectroscopy is used as the primary investigative tool due to the connection of the emitted photoelectrons to the electronic structure of the sample. The surveyed materials are of relevance for fundamental research and practical applications on their own, but also serve as archetypes for the photoemission techniques presented throughout the four main chapters of this thesis. The techniques are therefore outlined with their adaptation to other systems in mind and a special focus on the proper description of the final state. The most basic description of the final state that is still adequate for the evaluation of photoemission data is a plane wave. Its simplicity enables a relatively intuitive interpretation of photoemission data, since the initial and final state are related to one another by a Fourier transform and a geometric factor in this approximation. Moreover, the initial states of some systems can be reconstructed in three dimensions by combining photoemission measurements at various excitation energies. This reconstruction can even be carried out solely based on experimental data by using suitable iterative algorithms. Since the approximation of the final state in the photoemission process by a plane wave is not valid in all instances, knowledge on the limitations of its applicability is indispensable. This can be gained by a comparison to experimental data as well as calculations with a more detailed description of the photoemission final state. One possible appraoch is based on independently emitting atoms where the coherent superposition of partial, atomic final states produces the total final state. This approach can also be used for more intricate studies on organic thin films. To this end, experimental data can be related to theoretical calculations to gain extensive insights into the structural and electronic properties of molecules in organic thin films.},
  subject      = {ARPES},
  language  = {en}
}
@phdthesis{Huppmann2020,
  author    = {Huppmann, Sophia},
  title     = {Atomlagenabscheidung von Oxidschichten auf Edelmetalloberfl{\"a}chen und deren Haftung},
  doi       = {10.25972/OPUS-20708},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-207085},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2020},
  abstract  = {Ziel dieser Arbeit war die Untersuchung einer Passivierungsschicht auf Silber, um es vor Degradation unter Feuchte oder Schadgasen zu sch{\"u}tzen. Dazu wurden Al\(_2\)O\(_3\) und Ta\(_2\)O\(_5\) mittels Atomlagenabscheidung (atomic layer deposition: ALD) auf polykristallinen Silberoberfl{\"a}chen abgeschieden und deren Wachstum und Haftung analysiert. Zum Vergleich wurden die Edelmetalle Gold und Platin herangezogen. Die Beurteilung der Barriereeigenschaften gegen{\"u}ber Schadgas erfolgte mittels einer Ozon-Behandlung in der ALD-Prozesskammer. Es zeigte sich, dass nur ALD-Schichten, die bis zu eine Abscheidetemperatur von unter 140~°C abgeschieden wurden, eine ausreichende Barrierewirkung liefern konnten. Erkl{\"a}rt werden konnte dieses Ph{\"a}nomen durch unterschiedliche Wachtumsregime f{\"u}r unterschiedliche Abscheidetemperaturen zwischen 100 und 300~°C, die in einer temperaturabh{\"a}ngigen Bedeckung der Silberoberfl{\"a}che resultieren. W{\"a}hrend bei niedrigen Temperaturen eine geschlossene Schicht aufw{\"a}chst, findet ALD-Wachstum bei h{\"o}heren Temperaturen, beginnend {\"u}ber 115~°C, nur an Korngrenzen, Stufenkanten und Defekten statt. Es wurden verschiedene Oberfl{\"a}chenbehandlungen untersucht und nur eine Vorbehandlung mit H\(_2\)O bei 100~°C in der ALD-Prozesskammer konnte auch bei h{\"o}heren Temperaturen zu einem geschlossenen Schichtwachstum f{\"u}hren. In-vacuo XPS Untersuchungen der ersten Zyklen des Al\(_2\)O\(_3\)-Wachstums bei 100 und 200~°C auf Silber wurden miteinander und mit einer Silizium Referenzprobe verglichen. Bei beiden Wachstumstemperaturen kam es nicht zur Oxidation von Ag. Ab dem ersten TMA-Puls konnten Al-Verbindungen auf der Oberfl{\"a}che nachgewiesen werden. Es zeigte sich, dass TMA auf der Ag-Oberfl{\"a}che zu Methylaluminium und Methylresten dissoziieren und an Adsorbaten anbinden kann. Zus{\"a}tzlich zeigte sich ein erh{\"o}htes, nicht ges{\"a}ttigtes Wachstumsverhalten bei 200~°C, das {\"u}ber einen Sauerstoffdiffusionsprozess erkl{\"a}rt werden kann. Sauerstoff-Verunreinigungen, die sich in der Silberschicht befinden, konnten {\"u}ber Korngrenzendiffusion an die Oberfl{\"a}che gelangen und dort mit TMA reagieren. Aufgrund von Oberfl{\"a}chendiffusion bei h{\"o}heren Temperaturen gab es eine stabile Adsorption nur an Korngrenzen, Stufenkanten und Defekten. Nur die Si-Oberfl{\"a}che zeigte ein typisches ALD-Wachstum. Auf Pt und Au lag unabh{\"a}ngig von weiteren Vorbehandlungen bei allen Beschichtungstemperaturen ein geschlossenes ALD-Anwachsen vor. Damit eignete sich Au gut um die Barriere-Eigenschaften der ALD-Schicht gegen Feuchtigkeit in Abh{\"a}ngigkeit von der Wachstumstemperatur nachzuweisen. Dies wurde mit einer cyanidischen {\"A}tzl{\"o}sung getestet. W{\"a}hrend f{\"u}r eine Barriere gegen Ozon bereits eine d{\"u}nne geschlossene Schicht, abgeschieden bei 100~°C ausreicht, musste gegen die {\"A}tzl{\"o}sung eine h{\"o}here Beschichtungstemperatur verwendet werden. F{\"u}r die Bewertung der Haftung der Passivierungsschicht wurde neben den {\"u}blichen einfachen Tesatest und Schertest, ein pneumatischer Haftungstest entwickelt und eingesetzt. Daf{\"u}r wurde die Methode des Blistertest angepasst, der urspr{\"u}nglich f{\"u}r die Bestimmung der Haftung organischer Schichten, wie beispielsweise Kleber und Lacke, eingesetzt wurde, sodass er sich f{\"u}r die Untersuchung d{\"u}nner Schichten eignet. Dazu wurde die zu testende Grenzfl{\"a}che mittels eines Si-Tr{\"a}gers mechanisch unterst{\"u}tzt. Hierdurch kann die Deformation der Schicht minimiert werden und es kommt stattdessen zu einem Bruch. Die Delamination der Testschicht wurde durch das Anlegen des hydrostatischen Drucks erreicht, was eine gleichm{\"a}ßige Kraftverteilung gew{\"a}hrleistet. Die Proben ließen sich mittels Standard-D{\"u}nnfilmtechnologie herstellen und k{\"o}nnen damit industriell gut eingesetzt werden. Sowohl der Messaufbau als auch die Probenpr{\"a}paration wurden in dieser Arbeit vorgestellt. Es wurde mittels der beiden Bondmaterialien AuSn und Indium die maximal bestimmbare Adh{\"a}sionsspannung evaluiert und daf{\"u}r Werte von (0,26 \(\pm\) 0,03) \(\cdot 10^9 \) Pa f{\"u}r AuSn und (0,09 \(\pm\) 0,01) \(\cdot 10^9 \) Pa f{\"u}r In bestimmt. Da im In bereits bei sehr niedrigen Dr{\"u}cken ein koh{\"a}sives Versagen auftritt, eignet sich AuSn besser f{\"u}r die Messung anderer Grenzfl{\"a}chen. Damit wurden schließlich die Grenzfl{\"a}chen ALD-Al\(_2\)O\(_3\) und ALD-Ta\(_2\)O\(_5\) auf Ag mit H\(_2\)O-Vorbehandlung sowie ALD-Al\(_2\)O\(_3\) auf Pt untersucht. Es wurden die folgenden Adh{\"a}sionsspannungen erreicht: F{\"u}r ALD-Al\(_2\)O\(_3\) auf Ag: (0,23 \(\pm\) 0,01) \(\cdot 10^9 \) Pa, f{\"u}r ALD-Ta\(_2\)O\(_5\) auf Ag: (0,15 \(\pm\) 0,03) \(\cdot 10^9 \) Pa und f{\"u}r ALD-Al\(_2\)O\(_3\) auf Pt: (0,20 \(\pm\) 0,01) \(\cdot 10^9 \) Pa. Somit wurde best{\"a}tigt, dass mit Hilfe der Vorbehandlung der Ag-Oberfl{\"a}che die ALD-Al\(_2\)O\(_3\)-Schicht nicht nur geschlossen ist, sondern auch ausreichend gut haftet und sich damit hervorragend als Barriere eignet.},
  subject      = {Aluminiumoxide},
  language  = {de}
}
@phdthesis{Goetz2019,
  author    = {G{\"o}tz, Sebastian Reinhold},
  title     = {Nonlinear spectroscopy at the diffraction limit: probing ultrafast dynamics with shaped few-cycle laser pulses},
  doi       = {10.25972/OPUS-19213},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-192138},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2019},
  abstract  = {An experimental setup for probing ultrafast dynamics at the diffraction limit was developed, characterized and demonstrated in the scope of the thesis, aiming for optical investigations while simultaneously approaching the physical limits on the length and timescale. An overview of this experimental setup was given in Chapter 2, as well as the considerations that led to the selection of the individual components. Broadband laser pulses with a length of 9.3 fs, close to the transform limit of 7.6 fs, were focused in a NA = 1.4 immersion oil objective, to the diffraction limit of below 300 nm (FWHM). The spatial focus shape was characterized with off-resonance gold nanorod scatterers scanned through the focal volume. For further insights into the functionality and limitations of the pulse shaper, its calibration procedure was reviewed. The deviations between designed and experimental pulse shapes were attributed to pulse-shaper artifacts, including voltage-dependent inter-layer as well as intra-layer LCD-pixel crosstalk, Fabry-P{\´e}rot-type reflections in the LCD layers, and space-time coupling. A pixel-dependent correction was experimentally carried out, which can be seen as an extension of the initial calibration to all possible voltage combinations of the two LCD layers. The capabilities of the experimental setup were demonstrated in two types of experiments, targeting the nonlinearity of gold (Chapter 3) as well as two-dimensional spectroscopy at micro-structured surfaces (Chapter 4). Investigating thin films, an upper bound for the absolute value for the imaginary part of the nonlinear refractive index of gold could be set to |n′′ 2 (Au)| < 0.6·10-16 m2/W, together with |n′ 2 (Au)| < 1.2·10-16 m2/W as an upper bound for the absolute value of the real part. Finite-difference time-domain simulations on y-shaped gold nanostructures indicated that a phase change of ∆Φ ≥ 0.07 rad between two plasmonic modes would induce a sufficient change in the spatial contrast of emission to the far-field to be visible in the experiment. As the latter could not be observed, this value of ∆Φ was determined as the upper bound for the experimentally induced phase change. An upper bound of 52 GW/cm2 was found for the damage threshold. In Chapter 4, a novel method for nonlinear spectroscopy on surfaces was presented. Termed coherent two-dimensional fluorescence micro-spectroscopy, it is capable of exploring ultrafast dynamics in nanostructures and molecular systems at the diffraction limit. Two-dimensional spectra of spatially isolated hotspots in structured thin films of fluorinated zinc phthalocyanine (F16ZnPc) dye were taken with a 27-step phase-cycling scheme. Observed artifacts in the 2D maps were identified as a consequence from deviations between the desired and the experimental pulse shapes. The optimization procedures described in Chapter 2 successfully suppressed the deviations to a level where the separation from the nonlinear sample response was feasible. The experimental setup and methods developed and presented in the scope of this thesis demonstrate its flexibility and capability to study microscopic systems on surfaces. The systems exemplarily shown are consisting of metal-organic dyes and metallic nanostructures, represent samples currently under research in the growing fields of organic semiconductors and plasmonics.},
  subject      = {Ultrakurzzeitspektroskopie},
  language  = {en}
}
@phdthesis{Lundt2019,
  author    = {Lundt, Nils},
  title     = {Strong light-matter coupling with 2D materials},
  doi       = {10.25972/OPUS-18733},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-187335},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2019},
  abstract  = {This publication is dedicated to investigate strong light-matter coupling with excitons in 2D materials. This work starts with an introduction to the fundamentals of excitons in 2D materials, microcavities and strong coupling in chapter 2. The experimental methods used in this work are explained in detail in chapter 3. Chapter 4 covers basic investigations that help to select appropriate materials and cavities for the following experiments. In chapter 5, results on the formation of exciton-polaritons in various materials and cavity designs are presented. Chapter 6 covers studies on the spin-valley properties of exciton-polaritons including effects such as valley polarization, valley coherence and valley-dependent polariton propagation. Finally, the formation of hybrid-polaritons and their condensation are presented in chapter 7.},
  subject      = {Exziton-Polariton},
  language  = {en}
}
@phdthesis{Gross2019,
  author    = {Groß, Heiko},
  title     = {Controlling Light-Matter Interaction between Localized Surface Plasmons and Quantum Emitters},
  doi       = {10.25972/OPUS-19209},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-192097},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2019},
  abstract  = {Metal nanostructures have been known for a long time to exhibit optical resonances via localized surface plasmons. The high electric fields in close proximity to the metal surface have prospects to dramatically change the dynamics of electronic transitions, such as an enhanced spontaneous decay rate of a single emitter. However, there have been two major issues which impede advances in the experimental realization of enhanced light-matter interaction. (i) The fabrication of high-quality resonant structures requires state-of-the-art patterning techniques in combination with superior materials. (ii) The tiny extension of the optical near-field requires precise control of the single emitter with respect to the nanostructure. This work demonstrates a solution to these problems by combining scanning probe and optical confocal microscopy. Here, a novel type of scanning probe is introduced which features a tip composed of the edge of a single crystalline gold sheet. The patterning via focused ion beam milling makes it possible to introduce a plasmonic nanoresonator directly at the apex of the tip. Numerical simulations demonstrate that the optical properties of this kind of scanning probe are ideal to analyze light-matter interaction. Detailed experimental studies investigate the coupling mechanism between a localized plasmon and single colloidal quantum dots by dynamically changing coupling strength via their spatial separation. The results have shown that weak interaction affects the shape of the fluorescence spectrum as well as the polarization. For the best probes it has been found that it is possible to reach the strong coupling regime at the single emitter level at room temperature. The resulting analysis of the experimental data and the proposed theoretical models has revealed the differences between the established far-field coupling and near-field coupling. It has been found that the broad bandwidth of plasmonic resonances are able to establish coherent coupling to multiple transitions simultaneously giving rise to an enhanced effective coupling strength. It has also been found that the current model to numerically calculate the effective mode volume is inaccurate in case of mesoscopic emitters and strong coupling. Finally, light-matter interaction is investigated by the means of a quantum-dot-decorated microtubule which is traversing a localized nearfield by gliding on kinesin proteins. This biological transport mechanism allows the parallel probing of a meta-surface with nm-precision. The results that have been put forward throughout this work have shed new light on the understanding of plasmonic light-matter interaction and might trigger ideas on how to more efficiently combine the power of localized electric fields and novel excitonic materials.},
  subject      = {Plasmon},
  language  = {en}
}
@phdthesis{Strauss2018,
  author    = {Strauß, Micha Johannes},
  title     = {Molekularstrahlepitaxie von niederdimensionalen GaInAs(N) Systemen f{\"u}r AlGaAs Mikroresonatoren},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-159024},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2018},
  abstract  = {Die Erforschung von Quantenpunkten mit ihren quantisierten, atom{\"a}hnlichen Zust{\"a}nden, bietet eine Vielzahl von M{\"o}glichkeiten auf dem Weg zum Quantencomputer und f{\"u}r Anwendungen wie Einzelphotonenquellen und Quantenpunktlasern. Vorangegangene Studien haben grundlegend gezeigt, wie Quantenpunkte in Halbleiterresonatoren integriert und mit diesen gekoppelt werden k{\"o}nnen. Dazu war es zum einen notwendig, die Quantenpunkte und ihr epitaktisches Wachstum besser zu verstehen und zu optimieren. Zum anderen mussten die Bragg-Resonatoren optimiert werden, sodass G{\"u}ten von bis zu 165.000 realisiert werden konnten. Eingehende Studien dieser Proben zeigten im Anschluss einen komplexeren Zusammenhang von Q-Faktor und T{\"u}rmchendurchmesser. Man beobachtet eine quasi periodische Oszillation des Q-Faktors mit dem Pillar Durchmesser. Ein Faktor f{\"u}r diese Oszillation ist die Beschaffenheit der Seitenflanken des Resonatort{\"u}rmchens, bedingt durch die unterschiedlichen Eigenschaften von AlAs und GaAs bei der Prozessierung der T{\"u}rmchen. Dar{\"u}ber hinaus wurden in der Folge auf den Grundlagen dieser Strukturen sowohl optisch als auch elektrisch gepumpte Einzelphotonenquellen realisiert. Da in diesen Bauteilen auch die Lage des Quantenpunkts innerhalb des Resonatort{\"u}rmchens einen erheblichen Einfluss auf die Effizienz der Kopplung zwischen Resonator und Quantenpunkt hat, war das weitere Ziel, die Quantenpunkte kontrolliert zu positionieren. Mit einer gezielten Positionierung sollte es m{\"o}glich sein, ein Resonatort{\"u}rmchen direkt {\"u}ber dem Quantenpunkt zu plazieren und den Quantenpunkt somit in das Maximum der optischen Mode zu legen. Besondere Herausforderung f{\"u}r die Aufgabenstellung war, Quantenpunkte in einem Abstand von mind. der H{\"a}lfte des angestrebten T{\"u}rmchendurchmessers, d.h 0,5 μm bis 2 μm, zu positionieren. Die Positionierung musste so erfolgen, dass nach dem Wachstum eines AlAs/GaAs DBR Spiegel {\"u}ber den Quantenpunkten, Resonatort{\"u}rmchen zielgenau auf die Quantenpunkte prozessiert werden k{\"o}nnen. Es wurden geeignete Prozesse zur Strukturierung eines Lochgitters in die epitaktisch gewaschene Probe mittels Elektronenstrahllithographie entwickelt. F{\"u}r ein weiteres Wachstum mittels Molekularstrahlepitaxie, mussten die nasschemischen Reinigungsschritte sowie eine Reinigung mit aktivem Wasserstoff im Ultrahochvakuum optimiert werden, sodass die Probe m{\"o}glichst defektfrei {\"u}berwachsen werden konnte, die Struktur des Lochgitters aber nicht zerst{\"o}rt wurde. Es wurden erfolgreich InAs-Quantenpunkte auf die vorgegebene Struktur positioniert, erstmals in einem Abstand von mehreren Mikrometern zum n{\"a}chsten Nachbarn. Eine besondere Herausforderung war die Vorbereitung f{\"u}r eine weitere Prozessierung der Proben nach Quantenpunktwachstum. Eine Analyse mittels prozessierten Goldkreuzen, dass 30 \% der Quantenpunkte innerhalb von 50 nm und 60 \% innerhalb von 100 nm prozessiert wurden. In der Folge wurde mit der hier erarbeiteten Methode Quantenpunkte erfolgreich in DBR-Resonatoren sowie photonische Kristalle eingebaut Die gute Abstimmbarkeit von Quantenpunkten und die bereits gezeigte M{\"o}glichkeit, diese in Halbleiterresonatoren einbinden zu k{\"o}nnen, machen sie auch interessant f{\"u}r die Anwendung im Telekommunikationsbereich. Um f{\"u}r Glasfasernetze Anwendung zu finden, muss jedoch die Wellenl{\"a}nge auf den Bereich von 1300 nm oder 1550 nm {\"u}bertragen werden. Vorangegangene Ergebnisse kamen allerdings nur knapp an die Wellenl{\"a}nge von 1300nm. Eine fu ̈r andere Bauteile sowie f{\"u}r Laserdioden bereits h{\"a}ufig eingesetzte Methode, InAs-Quantenpunkte in den Bereich von Telekommunikationswellenla ̈ngen zu verschieben, ist die Verwendung von Stickstoff als weiteres Gruppe-V-Element. Bisherige Untersuchungen fokussierten sich auf Anwendungen in Laserdioden, mit hoher Quantenpunktdichte und Stickstoff sowohl in den Quantenpunkten als in den umgebenen Strukturen. Da InAsN-Quantenpunkte in ihren optischen Eigenschaften durch verschiedene Verlustmechanismen leiden, wurde das Modell eines Quantenpunktes in einem Wall (Dot-in-Well) unter der Verwendung von Stickstoff weiterentwickelt. Durch gezielte Separierung der Quantenpunkte von den stickstoffhaltigen Schichten, konnte e eine Emission von einzelnen, MBE-gewachsenen InAs Quantenpunkten von {\"u}ber 1300 nm gezeigt werden. Anstatt den Stickstoff direkt in die Quantenpunkte oder unmittelbar danach in die Deckschicht ein zu binden, wurde eine Pufferschicht ohne Stickstoff so angepasst, dass die Quantenpunkte gezielt mit Wellenl{\"a}ngen gr{\"o}ßer 1300 nm emittieren. So ist es nun m{\"o}glich, die Emission von einzelnen InAs Quantenpunkten jenseits dieser Wellenl{\"a}nge zu realisieren. Es ist nun daran, diese Quantenpunkte mit den beschriebenen Mikroresonatoren zu koppeln, um gezielt optisch und elektrisch gepumpte Einzelphotonenquellen f{\"u}r 1300nm zu realisieren.},
  subject      = {Quantenpunkt},
  language  = {de}
}