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Ziel dieser Arbeit war es, neue quantitative Messmethoden am Kleintier, insbesondere die Perfusionsmessung am Mäuseherz, zu etablieren. Hierfür wurde eine retrospektiv getriggerte T1-Messmethode entwickelt. Da bei retrospektiven Methoden keine vollständige Abtastung garantiert werden kann, wurde ein Verfahren gefunden, das mit Hilfe von Vorwissen über das gemessene Modell sehr effizient die fehlenden Daten interpolieren kann.
Mit Hilfe dieser Technik werden dynamische T1-Messungen mit hoher räumlicher und zeitlicher Auflösung möglich.
Dank der hohen Genauigkeit der T1-Messmethode lässt sich diese für die nichtinvasive Perfusionsmessung am Mäuseherz mittels der FAIR-ASL-Technik nutzen. Da auf Grund der retrospektiven Triggerung Daten an allen Positionen im Herzzyklus akquiriert werden, konnten T1- und Perfusionskarten nach der Messung zu beliebigen Punkten im Herzzyklus rekonstruiert werden.
Es bietet sich an, Techniken, die für die myokardiale Perfusion angewandt werden, auch für die Nierenperfusionsmessung zu verwenden, da die Niere in ihrer Rinde (Cortex) eine ähnlich hohe
Perfusion aufweist wie das Myokard. Gleichzeitig führen Nierenerkrankungen oftmals zu schlechter Kontrastmittelverträglichkeit, da diese bei Niereninsuffizienz u.U. zu lange im Körper verweilen und die Niere weiter schädigen. Auch deshalb sind die kontrastmittelfreien Spin-Labeling-Methoden hier interessant. Die FAIR-ASL-Technik ist jedoch an Mäusen in koronaler Ansicht für die Niere schlecht geeignet auf Grund des geringen Unterschieds zwischen dem markierten und dem Vergleichsexperiment. Als Lösung für dieses Problem wurde vorgeschlagen, die Markierungsschicht senkrecht zur Messschicht zu orientieren. Hiermit konnte die Sensitivität gesteigert und gleichzeitig die Variabilität der Methode deutlich verringert werden.
Mit Hilfe von kontrastmittelgestützten Messungen konnten auch das regionale Blutvolumen und das Extrazellularvolumen bestimmt werden. In den letzten Jahren hat das Interesse an Extrazellularvolumenmessungen zugenommen, da das Extrazellularvolumen stellvertretend für diffuse Fibrose gemessen werden kann, die bis dahin nichtinvasiven Methoden nicht zugänglich war. Die bisher in der Literatur verwendeten Quantifizierungsmethoden missachten den Einfluss, den das Hämatokrit auf den ECV-Wert hat. Es wurde eine neue Korrektur vorgeschlagen, die allerdings zusätzlich zur ECV-Messung auch eine RBV-Messung benötigt. Durch gleichzeitige Messung beider Volumenanteile konnte auch erstmals das Extrazellulare-Extravaskuläre-Volumen bestimmt werden.
Eine gänzlich andere kontrastmittelbasierte Methode in der MRT ist die Messung des chemischen Austauschs. Hierbei wirkt das Kontrastmittel nicht direkt beschleunigend auf die Relaxation, sondern der Effekt des Kontrastmittels wird gezielt durch HF-Pulse an- und ausgeschaltet. Durch den chemischen Austausch kann die Auswirkung der HF-Pulse akkumuliert werden. Bislang wurde bei solchen Messungen ein negativer Kontrast erzeugt, der ohne zusätzliche Vergleichsmessungen schwer detektierbar war. Im letzten Teil dieser Arbeit konnte eine neue Methode zur Messung des chemischen Austauschs gezeigt werden, die entgegen der aus der Literatur bekannten Methoden nicht Sättigung, sondern Anregung überträgt. Diese Änderung erlaubt es, einen echten positiven chemischen Austausch-Kontrast zu erzeugen, der nicht zwingend ein Vergleichsbild benötigt. Gleichzeitig ermöglicht die Technik, dadurch dass Anregung übertragen wird, die Phase der Anregung zu kontrollieren und nutzen. Eine mögliche Anwendung ist die Unterscheidung verschiedener Substanzen in einer Messung.
In der Summe wurden im Rahmen dieser Arbeit verschiedene robuste Methoden eta-
bliert, die die Möglichkeiten der quantitativen physiologischen MRT erweitern.
Das Ziel der vorliegenden Arbeit war die Entwicklung neuer, robuster Methoden der Spin-Lock-basierten MRT. Im Fokus stand hierbei vorerst die T1ρ-Quantifizierung des Myokards im Kleintiermodell. Neben der T1ρ-Bildgebung bietet Spin-Locking jedoch zusätzlich die Möglichkeit der Detektion ultra-schwacher, magnetischer Feldoszillationen. Die Projekte und Ergebnisse, die im Rahmen dieses Promotionsvorhabens umgesetzt und erzielt wurden, decken daher ein breites Spektrum der Spin-lock basierten Bildgebung ab und können grob in drei Bereiche unterteilt werden. Im ersten Schritt wurde die grundlegende Pulssequenz des Spin-Lock-Experimentes durch die Einführung des balancierten Spin-Locks optimiert. Der zweite Schritt war die Entwicklung einer kardialen MRT-Sequenz für die robuste Quantifizierung der myokardialen T1ρ-Relaxationszeit an einem präklinischen Hochfeld-MRT. Im letzten Schritt wurden Konzepte der robusten T1ρ-Bildgebung auf die Methodik der Felddetektion mittels Spin-Locking übertragen. Hierbei wurden erste, erfolgreiche Messungen magnetischer Oszillationen im nT-Bereich, welche lokal im untersuchten Gewebe auftreten, an einem klinischen MRT-System im menschlichen Gehirn realisiert.
Herzkreislauferkrankungen stellen die häufigsten Todesursachen in den Industrienationen dar. Die Entwicklung nichtinvasiver Bildgebungstechniken mit Hilfe der Magnetresonanz-Tomografie (MRT) ist daher von großer Bedeutung, um diese Erkrankungen frühzeitig zu erkennen und um die Entstehungsmechanismen zu erforschen. In den letzten Jahren erwiesen sich dabei genetisch modifzierte Mausmodelle als sehr wertvoll, da sich durch diese neue Bildgebungsmethoden entwickeln lassen und sich der Krankheitsverlauf im Zeitraffer beobachten lässt.
Ein große Herausforderung der murinen MRT-Bildgebung sind die die hohen Herzraten und die schnelle Atmung. Diese erfordern eine Synchronisation der Messung mit dem Herzschlag und der Atmung des Tieres mit Hilfe von Herz- und Atemsignalen. Konventionelle Bildgebungstechniken verwenden zur Synchronisation mit dem Herzschlag EKG Sonden, diese sind jedoch insbesondere bei hohen Feldstärken (>3 T) sehr störanfällig. In dieser Arbeit wurden daher neue Bildgebungsmethoden entwickelt, die keine externen Herz- und Atemsonden benötigen, sondern das MRT-Signal selbst zur Bewegungssynychronisation verwenden. Mit Hilfe dieser Technik gelang die Entwicklung neuer Methoden zur Flussbildgebung und der 3D-Bildgebung, mit denen sich das arterielle System der Maus qualitativ und quantitativ erfassen lässt, sowie einer neuen Methode zur Quantisierung der longitudinalen Relaxationszeit T1 im murinen Herzen. Die in dieser Arbeit entwickelten Methoden ermöglichen robustere Messungen des Herzkreislaufsystems. Im letzten Kapitel konnte darüber hinaus gezeigt werden dass sich die entwickelten Bildgebungstechniken in der Maus auch auf die humane Bildgebung übertragen lassen.
Die bSSFP-Sequenz kombiniert kurze Akquisitionszeiten mit einem hohen Signal-zu-Rausch-Verhältnis, was sie zu einer vielversprechenden Bildgebungsmethode macht. Im klinischen Alltag ist diese Technik jedoch bisher - abgesehen von vereinzelten Anwendungen - kaum etabliert. Die Hauptgründe hierfür sind Signalauslöschungen in Form von Bandingartefakten sowie der erzielte T2/T1-gewichtete Mischkontrast. Das Ziel dieser Dissertation war die Entwicklung von Methoden zur Lösung der beiden genannten Limitationen, um so eine umfassendere Verwendung von bSSFP für die MR-Diagnostik zu ermöglichen.
Magnetfeldinhomogenitäten, die im Wesentlichen durch Suszeptibilitätsunterschiede oder Imperfektionen seitens der Scannerhardware hervorgerufen werden, äußern sich bei der bSSFP-Bildgebung in Form von Bandingartefakten. Mit DYPR-SSFP (DYnamically Phase-cycled Radial bSSFP) wurde ein Verfahren vorgestellt, um diese Signalauslöschungen effizient zu entfernen. Während für bereits existierende Methoden mehrere separate bSSFP-Bilder akquiriert und anschließend kombiniert werden müssen, ist für die Bandingentfernung mittels DYPR-SSFP lediglich die Aufnahme eines einzelnen Bildes notwendig. Dies wird durch die neuartige Kombination eines dynamischen Phasenzyklus mit einer radialen Trajektorie mit quasizufälligem Abtastschema ermöglicht. Die notwendigen Bestandteile können mit geringem Aufwand implementiert werden. Des Weiteren ist kein spezielles Rekonstruktionsschema notwendig, was die breite Anwendbarkeit des entwickelten Ansatzes ermöglicht. Konventionelle Methoden zur Entfernung von Bandingartefakten werden sowohl bezüglich ihrer Robustheit als auch bezüglich der notwendigen Messzeit übertroffen.
Um die Anwendbarkeit von DYPR-SSFP auch jenseits der gewöhnlichen Bildgebung zu demonstrieren, wurde die Methode mit der Fett-Wasser-Separation kombiniert. Basierend auf der Dixon-Technik konnten so hochaufgelöste Fett- sowie Wasserbilder erzeugt werden. Aufgrund der Bewegungsinsensitivät der zugrunde liegenden radialen Trajektorie konnten die Messungen unter freier Atmung durchgeführt werden, ohne dass nennenswerte Beeinträchtigungen der Bildqualität auftraten. Die erzielten Ergebnisse am Abdomen zeigten weder Fehlzuordnungen von Fett- und Wasserpixeln noch verbleibende Bandingartefakte.
Ein Nachteil der gewöhnlichen Dixon-basierten Fett-Wasser-Separation ist es, dass mehrere separate Bilder zu verschiedenen Echozeiten benötigt werden. Dies führt zu einer entsprechenden Verlängerung der zugehörigen Messzeit. Abhilfe schafft hier die Verwendung einer Multiecho-Sequenz. Wie gezeigt werden konnte, ermöglicht eine derartige Kombination die robuste, bandingfreie Fett-Wasser-Separation in klinisch akzeptablen Messzeiten.
DYPR-SSFP erlaubt die Entfernung von Bandingartefakten selbst bei starken Magnetfeldinhomogenitäten. Dennoch ist es möglich, dass Signalauslöschungen aufgrund des Effekts der Intravoxeldephasierung verbleiben. Dieses Problem tritt primär bei der Bildgebung von Implantaten oder am Ultrahochfeld auf. Als Abhilfe hierfür wurde die Kombination von DYPR-SSFP mit der sogenannten z-Shim-Technik untersucht, was die Entfernung dieser Artefakte auf Kosten einer erhöhten Messzeit ermöglichte.
Die mit DYPR-SSFP akquirierten radialen Projektionen weisen aufgrund des angewendeten dynamischen Phasenzyklus leicht verschiedene Signallevel und Phasen auf. Diese Tatsache zeigt sich durch inkohärente Bildartefakte, die sich jedoch durch eine Erhöhung der Projektionsanzahl effektiv reduzieren lassen. Folglich bietet es sich in diesem Kontext an, Anwendungen zu wählen, bei denen bereits intrinsisch eine verhältnismäßig hohe Anzahl von Projektionen benötigt wird. Hierbei hat sich gezeigt, dass neben der hochaufgelösten Bildgebung die Wahl einer 3D radialen Trajektorie eine aussichtsreiche Kombination darstellt. Die in der vorliegenden Arbeit vorgestellte 3D DYPR-SSFP-Technik erlaubte so die isotrope bandingfreie bSSFP-Bildgebung, wobei die Messzeit im Vergleich zu einer gewöhnlichen bSSFP-Akquisition konstant gehalten werden konnte. Verbleibende, durch den dynamischen Phasenzyklus hervorgerufene Artefakte konnten effektiv mit einem Rauschunterdrückungsalgorithmus reduziert werden. Anhand Probandenmessungen wurde gezeigt, dass 3D DYPR-SSFP einen aussichtsreichen Kandidaten für die Bildgebung von Hirnnerven sowie des Bewegungsapparats darstellt.
Während die DYPR-SSFP-Methode sowie die darauf beruhenden Weiterentwicklungen effiziente Lösungen für das Problem der Bandingartefakte bei der bSSFP-Bildgebung darstellen, adressiert die vorgestellte RA-TOSSI-Technik (RAdial T-One sensitive and insensitive Steady-State Imaging) das Problem des bSSFP-Mischkontrasts. Die Möglichkeit der Generierung von T2-Kontrasten basierend auf der bSSFP-Sequenz konnte bereits in vorausgehenden Arbeiten gezeigt werden. Hierbei wurde die Tatsache ausgenutzt, dass der T1-Anteil des Signalverlaufs nach Beginn einer bSSFP-Akquisition durch das Einfügen von Inversionspulsen in ungleichmäßigen Abständen aufgehoben werden kann. Ein so akquiriertes Bild weist folglich einen reinen, klinisch relevanten T2-Kontrast auf. Die im Rahmen dieser Arbeit vorgestellte Methode basiert auf dem gleichen Prinzip, jedoch wurde anstelle einer gewöhnlichen kartesischen Trajektorie eine radiale Trajektorie in Kombination mit einer KWIC-Filter-Rekonstruktion verwendet. Somit können bei gleichbleibender oder sogar verbesserter Bildqualität aus einem einzelnen, mit RA-TOSSI akquirierten Datensatz verschiedene T2-Wichtungen als auch gewöhnliche T2/T1-Wichtungen generiert werden. Mittels Variation der Anzahl der eingefügten Inversionspulse konnte ferner gezeigt werden, dass es neben den besagten Wichtungen möglich ist, zusätzliche Kontraste zu generieren, bei denen verschiedene Substanzen im Bild ausgelöscht sind. Diese Substanzen können am Beispiel der Gehirnbildgebung Fett, graue Masse, weiße Masse oder CSF umfassen und zeichnen sich neben den reinen T2-Kontrasten durch eine ähnlich hohe klinische Relevanz aus. Die mögliche Bedeutung der vorgestellten Methode für die klinische Verwendung wurde durch Messungen an einer Gehirntumorpatientin demonstriert.
Zusammenfassend lässt sich sagen, dass die im Rahmen dieser Dissertation entwickelten Techniken einen wertvollen Beitrag zur Lösung der eingangs beschriebenen Probleme der bSSFP-Bildgebung darstellen. Mit DYPR-SSFP akquirierte Bilder sind bereits mit bestehender, kommerzieller Rekonstruktionssoftware direkt am Scanner rekonstruierbar. Die Software für die Rekonstruktion von RA-TOSSI-Datensätzen wurde für Siemens Scanner implementiert. Folglich sind beide Methoden für klinische Studien einsetzbar, was gleichzeitig den Ausblick dieser Arbeit darstellt.
In this work, we take a look at the connection of gamma-ray bursts (GRBs) and ultra-high-energy cosmic rays (UHECR) as well as the possibilities how to verify this connection. The currently most promising approach is based on the detection of high-energy neutrinos, which are associated with the acceleration of cosmic rays. We detail how the prompt gamma-ray emission is connected to the prediction of a neutrino signal. We focus on the interactions of photons and protons in this regard. At the example of the current ANTARES GRB neutrino analysis, we show the differences between numerical predictions and older analytical methods. Moreover, we discuss the possibilities how cosmic ray particles can escape from GRBs, assuming that UHECR are entirely made up of protons. For this, we compare the commonly assumed neutron escape model with a new component of direct proton escape. Additionally, we will show that the different components, which contribute to the cosmic ray flux, strongly depend on the burst parameters, and test the applicability on some chosen GRBs. In a further step, we continue with the considerations regarding the connection of GRBs and UHECR by connecting the GRB source model with the cosmic
ray observations using a simple cosmic ray propagation code. We test if it is possible to achieve the observed cosmic ray energy densities with our simple model and what the consequences are regarding the prompt GRB neutrino flux predictions as well as the cosmogenic neutrinos. Furthermore, we consider the question of neutrino lifetime and how it affects the prompt GRB neutrino flux predictions. In a final chapter, we show that it is possible to apply the basic source model with photohadronic interactions to other types of sources, using the example of the microquasar Cygnus X-3.
Nuclear magnetic resonance (NMR) imaging is a well-established imaging technique. If the achieved spatial resolution is below 100 um, it is usually denoted as magnetic resonance microscopy (MRM). The spatial resolution limit is on the order of a few um. As a downside, high resolution imaging is usually time-consuming and technological requirements are very sumptuous. Furthermore, miniaturization of the radiofrequency (RF) coil leading to a so-called microcoil is necessary; it also brings along detrimental effects. Therefore, there is a high potential for optimizing present MRM methods. Hence it is the aim of this work to improve and further develop present methods in MRM with focus on the RF coil and to apply those methods on new biological applications. All experiments were conducted on a Bruker 17.6 T system with a maximum gradient strength of 1 T/m and four RF receiver channels. Minimizing the RF coil dimensions, leads to increased artefacts due to differences in magnetic susceptibility of the coil wire and surrounding air. Susceptibility matching by immersing the coil in FC-43 is the most common approach that fulfills the requirements of most applications. However, hardly any alternatives are known for cases where usage of FC-43 is not feasible due to its specific disadvantages. Two alternative substances (bromotricholoromethane and Fomblin Y25) were presented and their usability was checked by susceptibility determination and demonstration experiments after shimming under practical conditions. In a typical MRM microcoil experiment, the sample volume is significantly smaller than the maximum volume usable for imaging. This mismatch has been optimized in order to increase the experiment efficiency by increasing the number of probe coils and samples used. A four-channel probehead consisting of four individual solenoid coils suited for cellular imaging of Xenopus laevis oocytes was designed, allowing simultaneous acquisition from four samples. All coils were well isolated and allowed quantitative image acquisition with the same spatial resolution as in single coil operation. This method has also been applied in other studies for increased efficiency: using X. laevis oocytes as a single cell model, the effect of chemical fixation on intracellular NMR relaxation times T1 and T2 and on diffusion was studied for the first time. Significant reduction of relaxation times was found in all cell compartments; after reimmersion in buffer, values return close to the initial values, but there were small but statistically significant differences due to residual formaldehyde. Embryos of the same species have been studied morphologically in different developmental stages. Wild type embryos were compared to embryos that had experienced variations in protein levels of chromosomal proteins HMGN and H1A. Significant differences were found between wild type and HMGN-modified embryos, while no difference was observed between wild type and H1-modified embryos. These results were concordant with results obtained from light microscopy and histology. The technique of molecular imaging was also performed on X. laevis embryos. Commercially available antibodies coupled to ultrasmall superparamagnetic iron oxide (USPIO) dextrane coated particles (MACS) served as a specific probe detectable by MRM, the aim being the detection of tissue specific contrast variations. Initially, the relaxivity of MACS was studied and compared to Resovist and VSOP particles. The iron concentration was determined quantitatively by using a general theoretical approach and results were compared to values obtained from mass spectroscopy. After incubation with MACS antibodies, intraembryonal relaxation times were determined in different regions of the embryo. These values allowed determination of local iron oxide particle concentrations, and specific binding could be distinguished from unspecific binding. Although applications in this work were focused on X. laevis oocytes and embryos, 3D-imaging on a beewolf head was also carried out in order to visualize the postpharyngeal gland. Additionally, an isolated beewolf antenna was imaged with a spatial resolution of (8 um)^3 for depiction of the antennal glands by using a microcoil that was specially designed for this sample. The experiments carried out in this work show that commercially available MRM systems can be significantly optimized by using small sample-adapted RF coils and by parallel operation of multiple coils, by which the sample throughput and thus time-efficiency is increased. With this optimized setup, practical use was demonstrated in a number of new biological applications.
Magnetic Resonance Imaging at field strengths up to 3 T, has become a default diagnostic modality for a variety of disorders and injuries, due to multiple reasons ranging from its non-invasive nature to the possibility of obtaining high resolution images of internal organs and soft tissues. Despite tremendous advances, MR imaging of certain anatomical regions and applications present specific challenges to be overcome. One such application is MR Musculo-Skeletal Imaging. This work addresses a few difficult areas within MSK imaging from the hardware perspective, with coil solutions for dynamic imaging of knee and high field imaging of hand.
Starting with a brief introduction to MR physics, different types of RF coils are introduced in chapter 1, followed by sections on design of birdcage coils, phased arrays and their characterization in chapter 2. Measurements, calculations and simulations, done during the course of this work, have been added to this chapter to give a quantitative feel of the concepts explained.
Chapter 3 deals with the construction of a phased array receiver for dynamic imaging of knee of a large animal model, i.e. minipig, at 1.5 T. Starting with details on the various aspects of an application that need to be considered when an MR RF array is designed, the chapter details the complex geometry of the region of interest in a minipig and reasons that necessitate a high density array. The sizes of the individual elements that constitute the array have been arrived at by studying the ratio of unloaded to loaded Q factors and choosing a size that provides the best ratio but still maintains a uniform SNR throughout the movement of the knee. To have a minimum weight and to allow mechanical movement of the knee, the Preamplifiers were located in a separate box. A movement device was constructed to achieve adjustable periodic movement of the knee of the anesthetized animal. The constructed array has been characterized for its SNR and compared with an existing product coil to show the improvement. The movement device was also characterized for its reproducibility. High resolution static images with anatomical details marked have been presented. The 1/g maps show the accelerations possible with the array. Snapshots of obtained dynamic images trace the cruciate ligaments through a cycle of movement of the animal's knee.
The hardware combination of a high density phased array and a movement device designed for a minipig's knee was used as a 'reference' and extended in chapter 4 for a human knee. In principle the challenges are similar for dynamic imaging of a human knee with regards to optimization of the elements, the associated electronics and the construction of the movement device. The size of the elements were optimized considering the field penetration / sensitivity required for the internal tissues. They were distributed around the curvature of the knee keeping in mind the acceleration required for dynamic imaging and the direction of the movement. The constructed movement device allows a periodic motion of the lower half of the leg, with the knee placed within the coil, enabling visualization of the tissues inside, while the leg is in motion. Imaging has been performed using dynamic interleaved acquisition sequence where higher effective TR and flip angles are achieved due to a combination of interleaving and segmentation of the sequence. The movement device has been characterized for its reproducibility while the SNR distribution of the constructed RF array has been compared with that of a commercially available standard 8 channel array. The results show the improvement in SNR and acceleration with the constructed geometry. High resolution static images, dynamic snapshots and the 3D segmentation of the obtained images prove the usefulness of the complete package provided in the design, for performing dynamic imaging at a clinically relevant field strength.
A simple study is performed in chapter 5 to understand the effects of changes in overlap for coil configurations with different loads and at different frequencies. The noise levels of individual channels and the correlation between them are plotted against subtle changes in overlap, at 64 and 123 MHz. SNR for every overlap setup is also measured and plotted. Results show that achieving critical overlap is crucial to obtain the best possible SNR in those coil setups where the load offered by the sample is low.
Chapter 6 of the thesis work deals with coil design for high field imaging of hand and wrists at 7 T, with an aim to achieve ultra high resolution imaging. At this field strength due to the increase in dielectric effects and the resulting decrease in homogeneity, whole body transmit coils are impractical and this has led engineers to design local transmit coils, for specific anatomies. While transmit or transceive arrays are usually preferred, to mitigate SAR effects, the spatial resolution obtained is limited. It is shown that a solution to this, with regards to hand imaging, can be a single volume transmit coil, along with high density receive arrays optimized for different regions of the hand. The use of a phased array for reception provides an increased SNR / penetration under high resolution. A volume transmit coil could pose issues in homogeneity at 7 T, but the specific anatomy of hand and wrist, with comparatively less water content, limits dielectric effects to have homogeneous B_1+ profile over the hand. To this effect, a bandpass birdcage and a 12 channel receive array are designed and characterized. Images of very high spatial resolution (0.16 x 0.16 x 0.16 mm3) with internal tissues marked are presented. In vivo 1/g maps show that an acceleration of up to 3 is possible and the EM simulation results presented show the uniform field along with SAR hotspots in the hand. To reduce the stress created due to the 'superman' position of imaging, provisions in the form of a holder and a hand rest have been designed and presented. Factors that contributed to the stability of the presented design are also listed, which would help future designs of receive arrays at high field strengths.
In conclusion, the coils and related hardware presented in this thesis address the following two aspects of MSK imaging: Dynamic imaging of knee and High resolution imaging of hand / wrist. The presented hardware addresses specific challenges and provides solutions. It is hoped that these designs are steps in the direction of improving the existing coils to get a better knowledge and understanding of MSK diseases such as Rheumatoid Arthritis and Osteoarthritis. The hardware can aid our study of ligament reconstruction and development. The high density array and transmit coil design for hand / wrist also demonstrates the benefits of the obtained SNR at 7 T while maintaining SAR within limits. This design is a contribution towards optimizing hardware at high field strength, to make it clinically acceptable and approved by regulatory bodies.
The subject of this thesis is the growth of Hg\(_{1-x}\)Cd\(_2\)Te layers via molecular beam epitaxy (MBE).
This material system gives rise to a number of extraordinary physical phenomena related to its electronic band structure and therefore is of fundamental interest in research.
The main results can be divided into three main areas, the implementation of a temperature measurement system based on band edge thermometry (BET), improvements of CdTe virtual substrate growth and the investigation of Hg\(_{1-x}\)Cd\(_2\)Te for different compositions.
Contents List of Publications 1 Introduction 2 Basic concepts and instrumentation 2.1 Mathematical description of femtosecond laser pulses 2.2 Optical quantities and measurements 2.2.1 Intensity 2.2.2 Absorbance and Beer-Lambert law 2.3 Laser system 2.4 General software framework for scientific data acquisition and simulation 2.4.1 Core components 2.4.2 Program for executing a single measurement sequence 2.4.3 Scan program 2.4.4 Evolutionary algorithm optimization program 2.4.5 Applications of the software framework 2.5 Summary 3 Generation of ultrabroadband femtosecond pulses in the visible 3.1 Nonlinear optics 3.1.1 Nonlinear polarization and frequency conversion 3.1.2 Phase matching 3.2 Optical parametric amplification 3.3 Noncollinear optical parametric amplifier 3.4 Considerations and experimental design of NOPA 3.4.1 Options for broadening the NOPA bandwidth 3.4.2 Experimental setup 3.5 NOPA pulse characterization 3.5.1 Second harmonic generation frequency-resolved optical gating 3.5.2 Transient grating frequency-resolved optical gating 3.6 Compression and shaping methods for NOPA pulses 3.6.1 Grating compressor 3.6.2 Prism compressor 3.6.3 Chirped mirrors 3.6.4 Detuned zero dispersion compressor 3.6.5 Deformable mirror pulse shaper 3.6.6 Liquid crystal pulse shaper 3.7 Liquid crystal pulse shaper 3.7.1 Femtosecond pulse shapers 3.7.2 Experimental design and parameters 3.7.3 Optical setup of the LC pulse shaper 3.7.4 Calibrations of the pulse shaper 3.8 Adaptive pulse compression 3.8.1 Closed loop pulse compression 3.8.2 Open loop pulse compression 3.9 Conclusions 4 Coherent optical two-dimensional spectroscopy 4.1 Introduction 4.2 Theory of third order nonlinear optical spectroscopies 4.2.1 Response function, electric fields, and signal field 4.2.2 Signal detection with spectral interferometry 4.2.3 Evaluation of two-dimensional spectra and phasing 4.2.4 Selection and classification of terms in induced nonlinear polarization 4.2.5 Oscillatory character of measured signal 4.3 Previous experimental implementations 4.4 Inherently phase-stable setup using conventional optics only 4.4.1 Manipulation of pulse pairs as a basis for stability 4.4.2 Experimental setup 4.4.3 Measurement procedure 4.4.4 Data evaluation 4.5 First experimental results 4.5.1 Demonstration of phase stability 4.5.2 2D spectrum of Nile Blue at room temperature 4.6 Summary and outlook 5 Product accumulation for ultrasensitive femtochemistry 5.1 The problem of sensitivity in femtochemistry 5.2 Accumulation for increased sensitivity 5.2.1 Comparison of conventional and accumulative sensitivity 5.2.2 Schematics and illustrative example 5.3 Experimental setup 5.4 Calibration and modeling of accumulation 5.5 Experiments on indocyanine green 5.5.1 Calibration of the setup 5.5.2 Chirped pulse excitation 5.5.3 Adaptive pulse shaping 5.6 Conclusions 6 Ultrafast photoconversion of the green fluorescent protein 6.1 Green fluorescent protein 6.2 Experimental setup for photoconversion of GFP 6.3 Calibration of the setup for GFP 6.3.1 Model for concentration dynamics of involved GFP species 6.3.2 Estimate of sensitivity 6.4 Excitation power study 6.5 Time-resolved two-color experiment 6.6 Time-delayed unshaped 400 nm – shaped 800 nm pulse excitation 6.6.1 Inducing photoconversion with chirped pulses 6.6.2 Photoconversion using third order phase pulses 6.7 Conclusions 7 Applications of the accumulative method to chiral systems 7.1 Introduction 7.2 Chiral asymmetric photochemistry 7.2.1 Continuous-wave circularly polarized light 7.2.2 Controlled asymmetric photochemistry using femtosecond laser pulses 7.3 Sensitive and fast polarimeter 7.3.1 Polarimeter setup 7.3.2 Detected signal I(t) 7.3.3 Angular amplification 7.3.4 Performance of the polarimeter 7.4 Molecular systems and mechanisms for enantioselective quantum control 7.4.1 Binaphthalene derivatives 7.4.2 Photochemical helicene formation 7.4.3 Spiropyran/merocyanine chiroptical molecular switches 7.5 Summary 8 Summary Zusammenfassung Bibliography Acknowledgements
Gegenstand dieser Arbeit sind Transportuntersuchungen an nanoelektronischen Bauelementen, wobei der Schwerpunkt in der Analyse von nichtlinearen Transporteigenschaften hybrider Strukturen stand. Zum Einsatz kamen auf GaAs basierende Heterostrukturen mit zum Beispiel kleinen Metallkontakten, die zu Symmetriebrechungen führen. Die Untersuchungen wurden bei tiefen Temperaturen bis hin zu Raumtemperatur durchgeführt. Es kamen zudem magnetische Felder zum Einsatz. So wurden zum einen der asymmetrische Magnetotransport in Nanostrukturen mit asymmetrischer Gateanordnung unter besonderer Berücksichtigung der Phononstreuung analysiert, zum anderen konnte ein memristiver Effekt in InAs basierenden Strukturen studiert werden. Des Weiteren konnte ein beachtlicher Magnetowiderstand in miniaturisierten CrAu-GaAs Bauelementen beobachtet werden, der das Potential besitzt, als Basis für extrem miniaturisierte Sensoren für den Betrieb bei Raumtemperatur eingesetzt zu werden.
Besides image contrast, imaging speed is probably the most important consideration in clinical magnetic resonance imaging (MRI). MR scanners currently operate at the limits of potential imaging speed, due to technical and physiological problems associated with rapidly switched gradient systems. Parallel imaging (parallel MRI or pMRI) is a method which allows one to significantly shorten the acquisition time of MR images without changing the contrast behavior of the underlying MR sequence. The accelerated image acquisition in pMRI is accomplished without relying on more powerful technical equipment or exceeding physiological boundaries. Because of these properties, pMRI is currently employed in many clinical routines, and the number of applications where pMRI can be used to accelerate imaging is increasing. However, there is also growing criticism of parallel imaging in certain applications. The primary reason for this is the intrinsic loss in the SNR due to the accelerated acquisition. In addition, other effects can also lead to a reduced image quality. Due to unavoidable inaccuracies in the pMRI reconstruction process, local and global errors may appear in the final reconstructed image. The local errors are visible as noise enhancement, while the global errors result in the so-called fold-over artifacts. The appearance and strength of these negative effects, and thus the image quality, depend upon different factors, such as the parallel imaging method chosen, specific parameters in the method, the sequence chosen, as well as specific sequence parameters. In general, it is not possible to optimize all of these parameters simultaneously for all applications. The application of parallel imaging in can lead to very pronounced image artifacts, i.e. parallel imaging can amplify errors. On the other hand, there are applications such as abdominal MR or MR angiography, in which parallel imaging does not reconstruct images robustly. Thus, the application of parallel imaging leads to errors. In general, the original euphoria surrounding parallel imaging in the clinic has been dampened by these problems. The reliability of the pMRI methods currently implemented is the main criticism. Furthermore, it has not been possible to significantly increase the maximum achievable acceleration with parallel imaging despite major technical advances. An acceleration factor of two is still standard in clinical routine, although the number of independent receiver channels available on most MR systems (which are a basic requirement for the application of pMRI) has increased by a factor of 3-6 in recent years. In this work, a novel and elegant method to address this problem has been demonstrated. The idea behind the work is to combine two methods in a synergistic way, namely non-Cartesian acquisition schemes and parallel imaging. The so-called non-Cartesian acquisition schemes have several advantages over standard Cartesian acquisitions, in that they are often faster and less sensitive to physiological noise. In addition, such acquisition schemes are very robust against fold-over artifacts even in the case of vast undersampling of k-space. Despite the advantages described above, non-Cartesian acquisition schemes are not commonly employed in clinical routines. A reason for that is the complicated reconstruction techniques which are required to convert the non-Cartesian data to a Cartesian grid before the fast Fourier transformation can be employed to arrive at the final MR image. Another reason is that Cartesian acquisitions are routinely accelerated with parallel imaging, which is not applicable for non-Cartesian MR acquisitions due to the long reconstruction times. This negates the speed advantage of non-Cartesian acquisition methods. Through the development of the methods presented in this thesis, reconstruction times for accelerated non-Cartesian acquisitions using parallel imaging now approach those of Cartesian images. In this work, the reliability of such methods has been demonstrated. In addition, it has been shown that higher acceleration factors can be achieved with such techniques than possible with Cartesian imaging. These properties of the techniques presented here lead the way for an implementation of such methods on MR scanners, and thus also offer the possibility for their use in clinical routine. This will lead to shorter examination times for patients as well as more reliable diagnoses.
Continuously increasing energy prices have considerably influenced the cost of living over the last decades. At the same time increasingly extreme weather conditions, drought-filled summers as well as autumns and winters with heavier rainfall and worsening storms have been reported. These are possibly the harbingers of the expected approaching global climate change. Considering the depletability of fossil energy sources and a rising distrust in nuclear power, investigations into new and innovative renewable energy sources are necessary to prepare for the coming future.
In addition to wind, hydro and biomass technologies, electricity generated by the direct conversion of incident sunlight is one of the most promising approaches. Since the syntheses and detailed studies of organic semiconducting polymers and fullerenes were intensified, a new kind of solar cell fabrication became conceivable. In addition to classical vacuum deposition techniques, organic cells were now also able to be processed from a solution, even on flexible substrates like plastic, fabric or paper.
An organic solar cell represents a complex electrical device influenced for instance by light interference for charge carrier generation. Also charge carrier recombination and transport mechanisms are important to its performance. In accordance to Coulomb interaction, this results in a specific distribution of the charge carriers and the electric field, which finally yield the measured current-voltage characteristics. Changes of certain parameters result in a complex response in the investigated device due to interactions between the physical processes. Consequently, it is necessary to find a way to generally predict the response of such a device to temperature changes for example.
In this work, a numerical, one-dimensional simulation has been developed based on the drift-diffusion equations for electrons, holes and excitons. The generation and recombination rates of the single species are defined according to a detailed balance approach. The Coulomb interaction between the single charge carriers is considered through the Poisson equation. An analytically non-solvable differential equation system is consequently set-up. With numerical approaches, valid solutions describing the macroscopic processes in organic solar cells can be found. An additional optical simulation is used to determine the spatially resolved charge carrier generation rates due to interference.
Concepts regarding organic semiconductors and solar cells are introduced in the first part of this work. All chapters are based on previous ones and logically outline the basic physics, device architectures, models of charge carrier generation and recombination as well as the mathematic and numerical approaches to obtain valid simulation results.
In the second part, the simulation is used to elaborate issues of current interest in organic solar cell research. This includes a basic understanding of how the open circuit voltage is generated and which processes limit its value. S-shaped current-voltage characteristics are explained assigning finite surface recombination velocities at metal electrodes piling-up local space charges. The power conversion efficiency is identified as a trade-off between charge carrier accumulation and charge extraction. This leads to an optimum of the power conversion efficiency at moderate to high charge carrier mobilities. Differences between recombination rates determined by different interpretations of identical experimental results are assigned to a spatially inhomogeneous recombination, relevant for almost all low mobility semiconductor devices.
This thesis investigated the potential of Compressed Sensing (CS) applied to Magnetic Resonance Imaging (MRI). CS is a novel image reconstruction method that emerged from the field of information theory. The framework of CS was first published in technical reports in 2004 by Candès and Donoho. Two years later, the theory of CS was published in a conference abstract and two papers. Candès and Donoho proved that it is possible, with overwhelming probability, to reconstruct a noise-free sparse signal from incomplete frequency samples (e.g., Fourier coefficients). Hereby, it is assumed a priori that the desired signal for reconstruction is sparse. A signal is considered “sparse“ when the number of non-zero elements is significantly smaller than the number of all elements. Sparsity is the most important foundation of CS. When an ideal noise-free signal with few non-zero elements is given, it should be understandably possible to obtain the relevant information from fewer Fourier coefficients than dictated by the Nyquist-Shannon criterion. The theory of CS is based on noise-free sparse signals. As soon as noise is introduced, no exact sparsity can be specified since all elements have signal intensities that are non-zero. However, with the addition of little or moderate noise, an approximate sparsity that can be exploited using the CS framework will still be given. The ability to reconstruct noisy undersampled sparse MRI data using CS has been extensively demonstrated. Although most MR datasets are not sparse in image space, they can be efficiently sparsified by a sparsifying transform. In this thesis, the data are either sparse in the image domain, after Discrete Gradient transformation, or after subtraction of a temporally averaged dataset from the data to be reconstructed (dynamic imaging). The aim of this thesis was to identify possible applications of CS to MRI. Two different algorithms were considered for reconstructing the undersampled sparse data with the CS concept. The Nonlinear Conjugate Gradient based technique with a relaxed data consistency constraint as suggested by Lustig et al. is termed Relaxed DC method. An alternative represents the Gradient or Steepest Descent algorithm with strict data consistency and is, therefore, termed the Strict DC method. Chapter 3 presents simulations illustrating which of these two reconstruction algorithms is best suited to recover undersampled sparse MR datasets. The results lead to the decision for the Strict DC method as reconstruction technique in this thesis. After these simulations, different applications and extensions of CS are demonstrated. Chapter 4 shows how CS benefits spectroscopic 19F imaging at 7 T, allowing a significant reduction of measurement times during in vivo experiments. Furthermore, it allows highly resolved spectroscopic 3D imaging in acceptable measurement times for in vivo applications. Chapter 5 introduces an extension of the Strict DC method called CS-CC (CS on Combined Coils), which allows efficient processing of sparse undersampled multi-coil data. It takes advantage of a concept named “Joint Sparsity“, which exploits the fact that all channels of a coil array detect the same sparse object weighted with the coil sensitivity profiles. The practical use of this new algorithm is demonstrated in dynamic radial cardiac imaging. Accurate reconstructions of cardiac motion in free breathing without ECG triggering were obtained for high undersampling factors. An Iterative GRAPPA algorithm is introduced in Chapter 6 that can recover undersampled data from arbitrary (Non-Cartesian) trajectories and works solely in the Cartesian plane. This characteristic makes the proposed Iterative GRAPPA computationally more efficient than SPIRiT. Iterative GRAPPA was developed in a preceding step to combine parallel imaging with CS. Optimal parameters for Iterative GRAPPA (e.g. number of iterations, GRAPPA kernel size) were determined in phantom experiments and verified by retrospectively undersampling and reconstructing a radial cardiac cine dataset. The synergistic combination of the coil-by-coil Strict DC CS method and Iterative GRAPPA called CS-GRAPPA is presented in Chapter 7. CS-GRAPPA allows accurate reconstruction of undersampled data from even higher acceleration factors than each individual method. It is a formulation equivalent to L1-SPIRiT but computationally more efficient. Additionally, a comparison with CS-CC is given. Interestingly, exploiting joint sparsity in CS-CC is slightly more efficient than the proposed CS-GRAPPA, a hybrid of parallel imaging and CS. The last chapter of this thesis concludes the findings presented in this dissertation. Future applications expected to benefit from CS are discussed and possible synergistic combinations with other existing MR methodologies for accelerated imaging are also contemplated.
The present thesis is concerned with the impact of alkali metal-doping on the electronic structure of semiconducting organic thin films. The organic molecular systems which have been studied are the polycyclic aromatic hydrocarbons picene, pentacene, and coronene. Motivated by reports about exceptional behavior like superconductivity and electronic correlations of their alkali metal-doped compounds, high quality films fabricated from the above named molecules have been studied. The electronic structure of the pristine materials and their doped compounds has been investigated using photoelectron spectroscopy. Core level and valence band studies of undoped films yield excellent photoemission spectra agreeing with or even outperforming previously reported data from the literature. Alkali metal-doping manifests itself in a uniform manner in the electronic structure for all probed samples: Opposed to reports from the literature about metallicity and even superconductivity in alkali metal-doped picene, pentacene, and coronene, all films exhibit insulating nature with an energy gap of the order of one electron-volt. Remarkably, this is independent of the doping concentration and the type of dopant, i.e., potassium, cesium, or sodium. Based on the interplay between narrow bandwidths in organic semiconductors and sufficiently high on-molecule Coulomb repulsion, the non-metallicity is attributed to the strong influence of electronic correlations leading to the formation of a Mott insulator. In the case of picene, this is consolidated by calculations using a combination of density functional theory and dynamical mean-field theory. Beyond the extensive considerations regarding electronic correlations, further intriguing aspects have been observed. The deposition of thin picene films leads to the formation of a non-equilibrium situation between substrate and film surface. Here, the establishment of a homogeneous chemical potential is hampered due to the only weak van der Waals-interactions between the molecular layers in the films. Consequently, spectral weight is measurable above the reference chemical potential in photoemission. Furthermore, it has been found that the acceptance of additional electrons in pentacene is limited. While picene and coronene are able to host up to three extra electrons, in pentacene the limit is already reached for one electron. Finally, further extrinsic effects, coming along with alkali metal-doping, have been scrutinized. The oxidation of potassium atoms induced by the reaction with molecular oxygen in the residual gas of the ultra-high vacuum system turned out to significantly influence the electronic structure of alkali metal-doped picene and coronene. Moreover, also the applied X-ray and UV irradiation caused a certain impact on the photoemission spectra. Surprisingly, both effects did not play a role in the studies of potassium-doped pentacene.
The present work addressed the influence of spins on fundamental processes in organic
semiconductors. In most cases, the role of spins in the conversion of sun light
into electricity was of particular interest. However, also the reversed process, an electric
current creating luminescence, was investigated by means of spin sensitive measurements.
In this work, many material systems were probed with a variety of innovative
detection techniques based on electron paramagnetic resonance spectroscopy.
More precisely, the observable could be customized which resulted in the experimental
techniques photoluminescence detected magnetic resonance (PLDMR), electrically
detected magnetic resonance (EDMR), and electroluminescence detected magnetic
resonance (ELDMR). Besides the commonly used continuous wave EPR spectroscopy,
this selection of measurement methods yielded an access to almost all intermediate
steps occurring in organic semiconductors during the conversion of light into electricity
and vice versa. Special attention was paid to the fact that all results were applicable
to realistic working conditions of the investigated devices, i.e. room temperature application and realistic illumination conditions.
Self-organized nanowires at semiconductor surfaces offer the unique opportunity to study electrons in reduced dimensions. Notably the dimensionality of the system determines it’s electronic properties, beyond the quasiparticle description. In the quasi-one-dimensional (1D) regime with weak lateral coupling between the chains, a Peierls instability can be realized. A nesting condition in the Fermi surface leads to a backfolding of the 1D electron band and thus to an insulating state. It is accompanied by a charge density wave (CDW) in real space that corresponds to the nesting vector. This effect has been claimed to occur in many surface-defined nanowire systems, such as the In chains on Si(111) or the Au reconstructions on the terraced Si(553) and Si(557) surfaces. Therefore a weak coupling between the nanowires in these systems has to be concluded. However theory proposes another state in the perfect 1D limit, which is completely destroyed upon slight coupling to higher dimensions. In this so-called Tomonaga-Luttinger liquid (TLL) state, the quasiparticle description of the Fermi liquid breaks down. Since the interaction between the electrons is enhanced due to the strong confinement, only collective excitations are allowed. This leads to novel effects like spin charge separation, where spin and charge degrees of freedom are decoupled and allowed to travel independently along the 1D-chain. Such rare state has not been realized at a surface until today. This thesis uses a novel approach to realize nanowires with improved confinement by studying the Au reconstructed Ge(001) surface. A new cleaning procedure using piranha solution is presented, in order to prepare a clean and long-range ordered substrate. To ensure optimal growth of the Au nanowires the phase diagram is extensively studied by scanning tunneling microscopy (STM) and low energy electron diffraction (LEED). The structural elements of the chains are revealed and described in high detail. Remarkably a structural phase transition of the delicate wire structure is found to occur above room temperature. Due to the lack of energy gaps a Peierls transition can be excluded as its origin. The transition is rather determined as 3D Ising type and therefore includes the substrate as well. Two hallmark properties of a TLL are found in the Au/Ge(001) wires by spectroscopic studies: Power-law suppression of the density of states (DOS) and universal scaling. This impressively proves the existence of a TLL in these chains and opens up a gateway to an atomic playground. Local studies and manipulations of a TLL state become possible for the first time. These comprise (i) doping by alkaline atoms, (ii) studies on chain ends and (iii) tunable coupling between the chains by additional Au atoms. Most importantly these manipulations offer input and test for theoretical models and predictions, and are thereby ultimately advancing the field of correlated electrons.
In this work, a bridge was built between the so-far separate fields of spin defects and 2D systems: for the first time, an optically addressable spin defect (VB-) in a van der Waals material (hexagonal boron nitride) was identified and exploited. The results of this thesis are divided into three topics as follows:
1.) Identification of VB-:
In the scope of this chapter, the defect ,the negatively charged boron vacancy VB-, is identified and characterized. An initialization and readout of the spin state can be demonstrated optically at room temperature and its spin Hamiltonian contributions can be quantified.
2.) Coherent Control of VB-:
A coherent control is required for the defect to be utilized for quantum applications, which
Nano-antennas are an emerging concept for the manipulation and control of optical fields at the sub-wavelength scale. In analogy to their radio- and micro-wave counterparts they provide an efficient link between propagating and localized fields. Antennas operating at optical frequencies are typically on the order of a few hundred nanometer in size and are fabricated from noble metals. Upon excitation with an external field the electron gas inside the antenna can respond resonantly, if the dimensions of the antenna are chosen appropriate. Consequently, the resonance wavelength depends on the antenna dimensions. The electron-density oscillation is a hybrid state of electron and photon and is called a localized plasmon resonance. The oscillating currents within the antenna constitute a source for enhanced optical near-fields, which are strongly localized at the metal surface.
A particular interesting type of antennas are pairs of metal particles separated by a small insulating gap. For anti-symmetric gap modes charges of opposite sign reside across the gap. The dominating field-components are normal to the metal surface and due to the boundary conditions they are sizable only inside the gap. The attractive Coulomb interaction increases the surface-charge accumulation at the gap and enhanced optical fields occur within the insulating gap. The Coulomb interaction increases with decreasing gap size and extreme localization and strongest intensity enhancement is expected for small gap sizes.
In this thesis optical antennas with extremely small gaps, just slightly larger than inter-atomic distances, are investigated by means of optical and electrical excitation. In the case of electrical excitation electron tunneling across the antenna gap is exploited.
At the beginning of this thesis little was known about the optical properties of antennas with atomic scale gaps. Standard measurement techniques of field confinement and enhancement involving well-separated source, sample and detector are not applicable at atomic length-scales due to the interaction of the respective elements. Here, an elegant approach has been found. It is based on the fact that for closely-spaced metallic particles the energy splitting of a hybridized mode pair, consisting of symmetric and anti-symmetric mode, provides a direct measure for the Coulomb interaction over the gap. Gap antennas therefore possess an internal ruler which sensitively reports the size of the gap.
Upon self-assembly side-by-side aligned nanorods with gap sizes ranging from 2 to 0.5nm could be obtained. These antennas exhibit various symmetric and anti-symmetric modes in the visible range. In order to reveal optical modes of all symmetries a novel scattering setup has been developed and is successfully applied. Careful analysis of the optical spectra and comparison to numerical simulations suggests that extreme field confinement and localization can occur in gaps down to 0.5 nm. This is possibly the limit of plasmonic enhancement since for smaller gaps electron tunneling as well as non-locality of the dielectric function affect plasmonic resonances.
The strongly confined and intense optical fields provided by atomic-scale gaps are ideally suited for enhanced light-matter interaction. The interplay of intense optical-frequency fields and static electric fields or currents is of great interest for opto-electronic applications. In this thesis a concept has been developed, which allows for the electrical connection of optical antennas. By means of numerical simulations the concept was first verified for antennas with gap sizes on the order of 25 nm. It could be shown, that by attaching the leads at positions of a field minimum the resonant properties are nearly undisturbed. The resonance wavelengths shift only by a small amount with respect to isolated antennas and the numerically calculated near-field intensity enhancement is about 1000, which is just slightly lower than for an unconnected antenna.
The antennas are fabricated from single-crystalline gold and exhibit superior optical and electrical properties. In particular, the conductivity is a factor of 4 larger with respect to multi-crystalline material, the resistance of the gap is as large as 1 TOhm and electric fields of at least 10^8 V/m can be continuously applied without damage. Optical scattering spectra reveal well-pronounced and tunable antenna resonances, which demonstrates the concept of electrically-connected antennas also experimentally.
By combining atomic-scale gaps and electrically-connected optical antennas a novel sub-wavelength photon source has been realized. To this end an antenna featuring an atomic scale gap is electrically driven by quantum tunneling across the antenna gap. The optical frequency components of this fluctuating current are efficiently converted to photons by the antenna. Consequently, light generation and control are integrated into a planar single-material nano-structure. Tunneling junctions are realized by positioning gold nanoparticles into the antenna gap, using an atomic force microscope. The presence of a stable tunneling junction between antenna and particle is demonstrated by measuring its distinct current-voltage characteristic. A DC voltage is applied to the junction and photons are generated by inelastically tunneling electrons via the enhanced local density of photonic states provided by the antenna resonance. The polarization of the emitted light is found to be along the antenna axis and the directivity is given by the dipolar antenna mode. By comparing electroluminescence and scattering spectra of different antennas, it has been shown that the spectrum of the generated light is determined by the geometry of the antenna. Moreover, the light generation process is enhanced by two orders of magnitude with respect to a non-resonant structure.
The controlled fabrication of the presented single-crystalline structures has not only pushed the frontiers of nano-technology, but the extreme confinement and enhancement of optical fields as well as the light generation by tunneling electrons lays a groundwork for a variety of fundamental studies and applications.
Field localization down to the (sub-)nanometer scale is a prerequisite for optical spectroscopy with near-atomic resolution. Indeed, recently first pioneering experiments have achieved molecular resolution exploiting plasmon-enhanced Raman scattering. The small modal volume of antennas with atomic-scale gaps can lead to light-matter interaction in the strong coupling regime. Quantum electro-dynamical effects such as Rabi splitting or oscillations are likely when a single emitter is placed into resonant structures with atomic-scale gaps.
The concept of electrically-connected optical antennas is expected to be widely applied within the emerging field of electro-plasmonics. The sub-wavelength photon source developed during this thesis
will likely gain attention for future plasmonic nanocircuits. It is envisioned that in such a circuit the optical signal provided by the source is processed at ultrafast speed and nanometer-scales on the chip and is finally converted back into an electronic signal. An integrated optical transistor could be realized by means of photon-assisted tunneling. Moreover, it would be interesting to investigate, if it is possible to imprint the fermionic nature of electrons onto photons in order to realize an electrically-driven source of single photons. Non-classical light sources with the potential for on-chip integration could be built from electrically-connected antennas and are of great interest for quantum communication. To this end single emitters could be placed in the antenna gap or single electron tunneling could be achieved by means of a single-channel quantum point contact or the Coulomb-blockade effect.
This work sheds light on different aspects of the silicon vacancy in SiC:
(1) Defect creation via irradiation is shown both with electrons and neutrons. Optical properties have been determined: the excitation of the vacancy is most efficient at excitation wavelengths between 720nm and 800nm. The PL decay yields a characteristic excited state lifetime of (6.3±0.6)ns.
(2) Defect engineering, meaning the controlled creation of vacancies in SiC with varying neutron fluence. The defect density could be engineered over eight orders of magnitude. On the one hand, in the sample with highest emitter density, the huge PL signal could even be enhanced by factor of five via annealing mechanisms. On the other hand, in the low defect density samples, single defects with photostable room temperature NIR emission were doubtlessly proven. Their lifetime of around 7ns confirmed the value of the transient measurement.
(3) Also electrical excitation of the defects has been demonstrated in a SiC LED structure.
(4) The investigations revealed for the first time that silicon vacancies can even exist SiC nanocrystals down to sizes of about 60 nm. The defects in the nanocrystals show stable PL emission in the NIR and even magnetic resonance in the 600nm fraction.
In conclusion, this work ascertains on the one hand basic properties of the silicon vacancy in silicon carbide. On the other hand, proof-of-principle measurements test the potential for various defect-based applications of the vacancy in SiC, and confirm the feasibility of e.g. electrically driven single photon sources or nanosensing applications in the near future.