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Für ein System ('ideales Gas') von N miteinander nicht wechselwirkenden Teilchen oder Zuständen, deren Wellenfunktionen φ(x) der Randbedingung φ(x)=0 für x aus Ŵ. gehorchen sollen, (W sei dabei die Oberfläche eines geschlossenen Hohlraumes Ŵ beliebiger Gestalt), ist von verschiedenen Autoren eine halbklassische Eigenwertdichteformel angegeben worden. Diese hängt nur linear über die Integrale V ,W und L über Ŵ (Volumen, Oberflächeninhalt und totale Krümmung von Ŵ) von der Gestalt. des Hohlraumes ab. Während von H. Weyl mathematisch bewiesen, werden konnte, daß der führende Volumterm im Gebiet großer Eigenwerte alle folgenden Terme überwiegt, konnte für den Oberflächenterm eine gleichartige Vermutung bisher nur numerisch begründet werden. Von dieser halbklassischen Eigenwertdichteformel ausgehend, werden die thermodynamischen Relationen des idealen Gases aufgebaut und einige Größen wie innere Energie, spezifische Wärme sowie die Oberflächen- und Krümmungs-Spannung für die Grenzfälle starker, ein Gebiet mittlerer und schwacher Entartung explizit berechnet, und zwar sowohl für die Fermi-Dirac als auch die Bose-Einstein-Statistik, als auch für deren klassischen Grenzfall, die Boltzmann-Maxwell-Statistik (s.Diagramm). Ausgenommen wird nur der Spezialfall der Einsteinkondensation, weil hier die (nur im Gebiet großer Eigenwerte gültige) halbklassische Eigenwertdichteformel nicht angewendet werden darf. Die in dieser Arbeit untersuchten quantenmechanisch bedingten Oberflächeneffekte idealer Quantengase sind experimentell bisher wenig untersucht worden; für Molekülgase sind sie verschwindend klein. Die experimentell beobachtete Oberflächenspannung stabiler Atomkerne wird von dem Modell, das den Kern als ideales, entartetes Fermigas der Temperatur T beschreibt, im wesentlichen richtig wiedergegeben. Mit dem in Kap. 3b) abgeleiteten Ausdruck für die Oberflächenspannung stark entarteter idealer Fermigase endlicher Temperatur kann eine Voraussage über die Oberflächenspannung angeregter Atomkerne gemacht werden.
The putative effects of dark matter are most easily explained by a collisionless fluid on cosmological scales and by Modified Newtonian Dynamics (MOND) on galactic scales. Hybrid MOND dark matter models combine the successes of dark matter on cosmological scales and those of MOND on galactic scales. An example of such a model is superfluid dark matter (SFDM) which postulates that this differing behavior with scale is caused by a single underlying substance with two phases. In this thesis, I highlight successful observational tests of SFDM regarding strong lensing and the Milky Way rotation curve. I also discuss three problems due to the double role of the aforementioned single underlying substance and show how these may be avoided. Finally, I introduce a novel Cherenkov radiation constraint for hybrid MOND dark matter models. This constraint is different from standard modified gravity Cherenkov radiation constraints because such hybrid models allow even non-relativistic objects like stars to emit Cherenkov radiation.
Different numerical approaches and algorithms arising in the context of modelling of cellular tissue evolution are discussed in this thesis. Being suited in particular to off-lattice agent-based models, the numerical tool of three-dimensional weighted kinetic and dynamic Delaunay triangulations is introduced and discussed for its applicability to adjacency detection. As there exists no implementation of a code that incorporates all necessary features for tissue modelling, algorithms for incremental insertion or deletion of points in Delaunay triangulations and the restoration of the Delaunay property for triangulations of moving point sets are introduced. In addition, the numerical solution of reaction-diffusion equations and their connection to agent-based cell tissue simulations is discussed. In order to demonstrate the applicability of the numerical algorithms, biological problems are studied for different model systems: For multicellular tumour spheroids, the weighted Delaunay triangulation provides a great advantage for adjacency detection, but due to the large cell numbers the model used for the cell-cell interaction has to be simplified to allow for a numerical solution. The agent-based model reproduces macroscopic experimental signatures, but some parameters cannot be fixed with the data available. A much simpler, but in key properties analogous, continuum model based on reaction-diffusion equations is likewise capable of reproducing the experimental data. Both modelling approaches make differing predictions on non-quantified experimental signatures. In the case of the epidermis, a smaller system is considered which enables a more complete treatment of the equations of motion. In particular, a control mechanism of cell proliferation is analysed. Simple assumptions suffice to explain the flow equilibrium observed in the epidermis. In addition, the effect of adhesion on the survival chances of cancerous cells is studied. For some regions in parameter space, stochastic effects may completely alter the outcome. The findings stress the need of establishing a defined experimental model to fix the unknown model parameters and to rule out further models.
The implementation of pump-probe experiments with ultrashort laser pulses enables the study of dynamical processes in atoms or molecules, which may provide a deeper inside in their physical origin. The application of this method to systems as nitrous oxide, which is not only a simple example for polyatomic molecules but which also plays a crucial role in the greenhouse effect, promises interesting and beneficial findings. This thesis presents, on the one hand, the technical extension of an existing experimental setup for high-harmonic generation (HHG) and ultra-fast laser physics by an extreme ultraviolet (XUV) spectrometer for the in-situ observation of the harmonic spectrum during ongoing measurements. The present setup enables the production of short laser pulse trains in the XUV spectral range with durations of a few hundred attoseconds (1 as = 10^−18 s) via HHG and supports to perform XUV-IR pump-probe experiments using the infrared (IR) driving field with durations of a few femtoseconds. Moreover, a reaction microscope is implemented, which enables the coincident detection of several charged particles emerging from an ionization or dissociation process and to reconstruct their full 3-D-momentum vectors. With this technique it is possible to perform time-resolved momentum spectroscopy of few-particle quantum systems. Here, the design and the calibration of the XUV spectrometer is presented as well as a first application to the analysis of experimental data by providing information on the produced photon energies. On the other hand, the results of an XUV-pump IR-probe measurement on nitrous oxide (N2O) are discussed. With the broad harmonic spectrum (∼ 17 − 45 eV) it is possible to address several states of the singly and doubly ionized cation. One reaction channel is the single ionization into a stable state of N2O+. Here, the coincidently measured photoelectron energies allow the observation of sidebands, which served to estimate the pulse durations of the involved XUV pulse trains as well as of the fundamental IR pulses. Additionally, single ionization of nitrous oxide can lead to a dissociation into a charged and a neutral fragment. The four respective dissociation channels are compared by presenting their branching ratios, kinetic energy release (KER) distributions and their dependencies on the time delay between pump and probe pulse. In the production of the dication, there are two competitive processes: direct double ionization considering photon energies above the double-ionization threshold, and autoionization of singly ionized and excited molecules in the case of photon energies near the double-ionization threshold. In both cases, the ionization leads to a Coulomb explosion into two charged fragments, where the N − N bond or the N − O bond may dissociate. The influence of the IR-probe field on the ionization yield and the KER was investigated for both dissociation channels and compared. In addition, the corresponding photoelectron energy spectra are presented, which show indications for autoionizing states being involved, and their dependence on the delay and the KER of the respective ions is analyzed.
Navigating a complex environment is assumed to require stable cortical representations of environmental stimuli. Previous experimental studies, however, show substantial ongoing remodeling at the level of synaptic connections, even under behaviorally and environmentally stable conditions. It remains unclear, how these changes affect sensory representations on the level of neuronal populations during basal conditions and how learning influences these dynamics.
Our approach is a joint effort between the analysis of experimental data and theory. We analyze chronic neuronal population activity data – acquired by out collaborators in Mainz – to describe population activity dynamics during basal dynamics and during learning (fear conditioning). The data analysis is complemented by the analysis of a circuit model investigating the link between a neural network’s activity and changes in its underlying structure.
Using chronic two-photon imaging data recorded in awake mouse auditory cortex, we reproduce previous findings that responses of neuronal populations to short complex sounds typically cluster into a near discrete set of possible responses. This means that different stimuli evoke basically the same response and are thus grouped together into one of a small set of possible response modes. The near discrete set of response modes can be utilized as a sensitive and robust means to detect and track changes in population activity over time. Doing so we find that sound representations are subject to a significant ongoing remodeling across the time span of days under basal conditions. Auditory cued fear conditioning introduces a bias into these ongoing dynamics, resulting in a differential generalization both on the level of neuronal populations and on the behavioral level. This means that sounds that are perceived similar to the conditioned stimulus (CS+) show an increased co-mapping to the same response mode the CS+ is mapped to. This differential generalization is also observed in animal behavior, where sounds similar to the CS+ result in the same freezing behavior as the CS+, whereas dissimilar sounds do not. These observations could provide a potential mechanism of stimulus generalization, which is one of the most common phenomena associated with post-traumatic stress disorder, on the level of neuronal populations.
To investigate how the aforementioned changes in neuronal population activity are linked to changes in the underlying synaptic connectivity, we devised a circuit model of excitatory and inhibitory neurons. We studied this firing rate model to investigate the effect of gradual changes in the network’s connectivity on its activity. Apart from an input dominated uni-stable regime (one response per stimulus independent of the network) and a network dominated uni-stable regime (one response per network independent of the stimulus), we also find a multi-stable regime for strong recurrent connectivity and a high ratio of inhibition to excitation. In this regime the model reproduces properties of neural population activity in mouse auditory cortex, including sparse activity, a broad distribution of firing rates, and clustering of stimuli into a near discrete set of response modes. This clustering in the multi-stable regime means that, not only can identical stimuli evoke different responses, depending on the network’s initial condition, but different stimuli can also evoke the same response.
Applying gradual drift to the network connectivity we find periods of stable responses, interrupted by abrupt transitions altering the stimulus response mapping. We study the mechanism underlying these transitions by analyzing changes in the fixed points of this network model, employing a method to numerically find all the fixed points of the system. We find that such abrupt transitions typically cannot be explained by the mere displacement of existing fixed points, but involve qualitative changes in the fixed point structure in the vicinity of the response trajectory. We conclude that gradual synaptic drift can lead to abrupt transitions in stimulus responses and that qualitative changes in the network’s fixed point topology underlie such transitions.
In summary we find that cortical networks display ongoing representational drift under basal conditions that is biased towards a differential generalization during fear conditioning. A circuit model is able to reproduce key characteristics of auditory cortex, including a clustering of stimulus responses into a near discrete set of response modes. Implementing synaptic drift into this model leads to periods of stable responses interrupted by abrupt transitions towards new responses.
In this thesis hard probes are studied in the partonic transport model BAMPS (Boltzmann Approach to MultiParton Scatterings). Employing Monte Carlo techniques, this model describes the 3+1 dimensional evolution of the quark gluon plasma phase in ultra-relativistic heavy-ion collisions by propagating all particles in space and time and carrying out their collisions according to the Boltzmann equation. Since hard probes are produced in hard processes with a large momentum transfer, the value of the running coupling is small and their interactions should be describable within perturbative QCD (pQCD). This work focuses on open heavy flavor, but also addresses the suppression of light parton jets, in particular to highlight differences due to the mass. For light partons, radiative processes are the dominant contribution to their energy loss. For heavy quarks, we show that also binary interactions with a running coupling and an improved Debye screening matched to hard-thermal-loop calculations play an important role. Furthermore, the impact of the mass in radiative interactions, prominently named the dead cone effect, and the interplay with the Landau-Pomeranchuk-Migdal (LPM) effect are studied in great detail. Since the transport model BAMPS has access to all medium properties and the space time information of heavy quarks, it is the ideal tool to study the dissociation and regeneration of J/psi mesons, which is also investigated in this thesis.
A synchrotron is a particular type of cyclic particle accelerator and the first accelerator concept to enable the construction of large-scale facilities [10], such as the largest particle accelerator in the world, the 27-kilometre-circumference Large Hadron Collider (LHC) by CERN near Geneva, Switzerland, the European Synchrotron Radiation Facility (ESRF) in Grenoble, France for the synchrotron radiation, the superconducting, heavy ion synchrotron SIS100 under construction for the FAIR facility at GSI, Darmstadt, Germany and so on. Unlike a cyclotron, which can accelerate particles starting at low kinetic energy, a synchrotron needs a pre-acceleration facility to accelerate particles to an appropriate initial value before synchrotron injection. A pre-acceleration can be realized by a chain of other accelerator structures like a linac, a microtron in case of electrons, for example, Proton and ion injectors Linac 4 and Linac 3 for the LHC, UNLAC as the injector for the SIS18 in GSI and in future the SIS18 as injector for the SIS100. The linac is a commonly used injector for the ion synchrotron and consists of some key components. The three main parts of a linac are: An ion source creating the particles, a buncher system or an RFQ followed by the main drift tube accelerator DTL. In order to meet the energy and the beam current requirement of a synchrotron injector linac, its cost is a remarkable percentage of the total facility costs.
However, the normal conducting linac operation at cryogenic temperatures can be a promising solution in improving the efficiency and reducing the costs of a linac. Synchrotron injectors operate at very low duty factor with beam pulse lengths in 1 micros to 100 micros range, as most of the time is needed to perform the synchrotron cycle. Superconducting linacs are not convenient, as they cannot efficiently operate at low duty factor and high beam currents.
The cryogenic operation of ion linacs is discussed and investigated at IAP in Frankfurt since around 2012 [1, 37]. The motivation was to develop very compact synchrotron injectors at reduced overall linac costs per MV of acceleration voltage. As the needed beam currents for new facilities are increasing as well, the new technology will also allow an efficient realization of higher injector linac energies, which is needed in that case. Operating normal conducting structures at cryogenic temperature exploits the significantly higher conductivity of copper at temperatures of liquid nitrogen and below. On the other hand, the anomalous skin effect reduces the gain in shunt impedance quite a bit[25, 31, 9]. Some intense studies and experiments were performed recently, which are encouraging with respect to increased field levels at linac operation temperatures between 30 K and 70 K [17, 24, 4, 23, 5, 8]. While these studies are motivated by applications in electron acceleration at GHz-frequencies, the aim of this paper is to find applications in the 100 to 700 MHz range, typical for proton and ion acceleration. At these frequencies, a higher impact in saving RF power is expected due to the larger skin depth, which is proportional to the frequency to the power of negative half with respect to the normal skin effect. On the other hand, it is assumed that the improvement in maximum surface field levels will be similar to what was demonstrated already for electron accelerator cavities. This should allow to find a good compromise between reduced RF power needs for achieving a given accelerator voltage and a reduced total linac length to save building costs.
A very important point is the temperature stability of the cavity surface during the RF pulse. This is of increasing importance the lower the operating temperature is chosen: the temperature dependence of the electric conductivity in copper gets rather strong below 80 K, as long as the RRR - value of the copper is adequate. It is very clear, that this technology is suited for low duty cycle operated cavities only - with RF pulse lengths below one millisecond. At longer pulses the cavity surface will be heated within the pulse to temperatures, where the conductivity advantage is reduced substantially. These conditions fit very well to synchrotron injectors or to pulsed beam power applications.
H – Mode structures of the IH – and of the CH – type are well-known to have rather small cavity diameters at a given operating frequency. Moreover, they can achieve effective acceleration voltage gains above 10 MV/m even at low beam energies, and already at room temperature operation[29]. With the new techniques of 3d – printing of stainless steel and copper components one can reduce cavity sizes even further – making the realization of complex cooling channels much easier.
Another topic are copper components in superconducting cavities – like power couplers. It is of great importance to know exactly the thermal losses at these surfaces, which can’t be cooled efficiently in an easy way.
In the framework of the LHC Injectors Upgrade Project (LIU), the CERN Proton Synchrotron Booster (PSB) went through major upgrades resulting in new effects to study, challenges to overcome and new parameter regimes to explore. To assess the achievable beam brightness limit of the machine, a series of experimental and computational studies in the transverse planes were performed. In particular, the new injection scheme induces optics perturbations that are strongly enhanced near the half-integer resonance. In this thesis, methods for dynamically measuring and correcting these perturbations and their impact on the beam performance will be presented. Additionally, the quality of the transverse beam distributions and strategies for improvement will be addressed. Finally, the space charge effects when dynamically crossing the half-integer resonance will be characterized. The results of these studies and their broader significance beyond the PSB will be discussed.
Classical light microscopy is one of the main tools for science to study small things. Microscopes and their technology and optics have been developed and improved over centuries, however their resolution is ultimately restricted physically by the diffraction of light based on its wave nature described by Maxwell’s equations. Hence, the nanoworld – often characterized by sub-100-nm structural sizes – is not accessible with classical far-field optics (apart from special x-ray laser concepts) since its lateral resolution scales with the wavelength.
It was not until the 20th century that various technologies emerged to circumvent the diffraction limit, including so-called near-field microscopy. Although conceptually based on Maxwell’s long known equations, it took a long time for the scientific community to recognize its powerful opportunities and the first embodiments of near-field microscopes were developed. One representative of them is the scattering-type Scanning Near-field Optical Microscope (s-SNOM). It is a Scanning Probe Microscope (SPM) that enables imaging and spectroscopy at visible light frequencies down to even radio waves with a sub-100-nm resolution regardless of the wavelength used. This work also reflects this wide spectral range as it contains applications from near-infrared light down to deep THz/GHz radiation.
This thesis is subdivided into two parts. First, new experimental capabilities for the s-SNOM are demonstrated and evaluated in a more technical manner. Second, among other things, these capabilities are used to study various transport phenomena in solids, as already indicated in the title.
On the technical side, preliminary studies on the suitability of the qPlus sensor – a novel scanning probe technology – for near-field microscopy are presented.
The scanning head incorporating the qPlus sensor–named TRIBUS – is originally intended and built for ultra-high vacuum, low temperature, and high resolution applications. These are desirable environments and properties for sensitive nearfield measurements as well. However, since its design was not planned for near-field measurements, several special technical and optical aspects have to be taken into account, among others the scanning tip design and a spring suspended measurement head.
In addition, in this thesis field-effect transistors are used as THz detectors in an s-SNOM for the first time. Although THz s-SNOM is already an emerging technology, it still suffers from the requirements of sophisticated and specialized infrastructure on both the detector and laser side. Field-effect transistors offer an alternative that is flexible, cost-efficient, room-temperature operating, and easy to handle. Here, their suitability for s-SNOM measurements, which in general require very sensitive and fast detectors, is evaluated.
In the scientific part of this thesis, electromagnetic surface waves on silver nanowires and the conductivity/charge carrier density in silicon are investigated. Both are completely different concepts of transport phenomena, but this already shows the general versatility of the s-SNOM as it can enter both fields. Silver nanowires are analysed by means of near-infrared radiation. Their plasmonic behaviour in this spectral region is studied complementing other simulations and studies in literature performed on them using for example far-field optics.
Furthermore, the surface wave imaging ability of the s-SNOM in the near-infrared regime is thoroughly investigated in this thesis. Mapping surface waves in the mid-infrared regime is widespread in the community, however for much smaller wavelengths there are several important aspects to be considered additionally, such as the smaller focal spot size.
After that, doped and photo-excited silicon substrates are investigated. As the characteristic frequencies of charge carriers in semiconductors – described by the plasma frequency and the Drude model – are within the THz range, the THz s-SNOM is very well suited to probe their behaviour and to reveal contrasts, which has already been shown qualitatively by numerous literature reports. Here, the photo-excitation enables to set and tune the charge carrier density continuously.
Furthermore, the analysis of all silicon samples focuses on a quantitative extraction of the charge carrier densities and doping levels ...
Optoelektronische THz-Systeme finden seit 1995 Anwendung in der Bildgebung. Alle bisherigen Systeme basieren dabei auf gepulsten Femtosekunden-Laserquellen und emittieren gepulste, breitbandige THz-Strahlung. In dieser Arbeit wird erstmals ein bildgebendes optoelektronisches Dauerstrich-THz-Svstem auf Basis von Photomischern als Emitter und Detektor vorgestellt. Zur Optimierung des Systems wurden im Rahmen dieser Arbeit die einzelnen Komponenten detailliert untersucht und insbesondere ihre Wechselwirkung im Rahmen einer Systembetrachtung analysiert. Für den Laborbetrieb wurde ein Zweifarben-Ti:Saphir-Laser entwickelt, der es ermöglicht, die beiden zu mischenden nah-infraroten Frequenzen in einem Verstärkermedium zu generieren. Für das bildgebende System wurde der Laser in unidirektionaler Ringkonfiguration mit zwei sich im Laserkristall kreuzenden Resonatoren verwendet. Zur Optimierung der als THz-Emitter verwendeten Photomischer wurde die generierte THz-Leistung von schnellen Photoschaltern basierend auf bei unterschiedlichen Temperaturen gewachsenem LT-GaAs gemessen. Es zeigt sich, dass neben der Ladungsträgereinfangzeit auch die effektive Ladungsträgermobilität mit der Wachstumstemperatur variiert. Sie nimmt zu höheren Wachstumstemperaturen hin ab. Für eine gegebene THz-Zielfrequenz muss das LT-GaAs Material so gewählt werden, dass es eine optimale elektrische Effizienz aufweist. Die so optimierten Photoschalter müssen in eine resonante Antennenstruktur eingebettet werden, um eine optimale THz-Abstrahlung zu ermöglichen. Je nach Anwendung kann die Antennenstruktur entweder breitbandig (d.h. breiter Abstimmbereich) mit vergleichsweise niedriger Abstrahlungseffizienz oder schmalbandig mit hoher Abstrahlungseffizienz gewählt werden. Das Schlüsselproblem beim Entwurf effizienter Photomischer ist jedoch die Fehlanpassung zwischen der Impedanz des Photoschalters und der Eingangsimpedanz der Antenne, die nur durch die Wahl einer geeigneten Antenne verbessert werden kann. Eine der ungeklärten Fragen bei der Entwicklung von leistungsfähigen Photomischern auf LT-GaAs-Basis für Dauerstrich- und hochrepetierlichen Pulsbetrieb war bisher der Einfluss der Feldabschirmung im Photoschalter. Zur Untersuchung des lokalen Feldes und seiner Abschirmung wurde ein zeitaufgelöstes Doppelpulsexperiment durchgeführt. Das beobachtete Abschirmverhalten ist, entgegen allen bisherigen Aussagen, nicht auf die Abschirmung durch Raumladungen. sondern auf die Abschirmung durch das elektrische THz-Strahlungsfeld (Nahfeld) zurückzuführen.
In this work the preparation of organic donor-acceptor thin films was studied. A chamber for organic molecular beam deposition was designed and integrated into an existing deposition system for metallic thin films. Furthermore, the deposition system was extended by a load-lock with integrated bake-out function, a chamber for the deposition of metallic contacts via stencil mask technique and a sputtering chamber. For the sublimation of the organic compounds several effusion cells were designed. The evaporation characteristic and the temperature profile within the cells was studied. Additionally, a simulation program was developed, which calculates the evaporation characteristics of different cell types. The following processes were integrated: evaporation of particles, migration on the cell walls and collisions in the gas phase. It is also possible to consider a temperature gradient within the cell. All processes can be studied separately and their relative strength can be varied. To verify the simulation results several evaporation experiments with different cell types were employed. The thickness profile of the prepared thin films was measured position-dependently. The results are in good agreement with the simulation. Furthermore, the simulation program was extended to the field of electron beam induced deposition (EBID). The second part of this work deals with the preparation and characterization of organic thin films. The focus hereby lies on the charge transfer salt (BEDT-TTF)(TCNQ), which has three known structure variants. Thin films were prepared by different methods of co-evaporation and were studied with optical microscopy, X-ray diffraction and energy dispersive X-ray spectroscopy (EDX).The formation of the monoclinic phase of (BEDT-TTF)(TCNQ) could be shown. As a last part tunnel structures were prepared as first thin film devices and measured in a He4 cryostat.
This work deals with the use of dielectrics with high permeability, so-called high-k dielectrics in organic thin-film field-effect transistors (FETs). The central part was the preparation of the high-k dielectric and its implementation in transistors, in which organic semiconductors were used as active layer. A field-effect transistor can be used to measure the charge carrier mobility. Employing high-k dielectrics the carrier concentration in the active layer can be greatly increased. In this way, high charge carrier concentrations in organic layers can be achieved without chemical doping. As high-k dielectric strontium titanate (STO) was selected. It is also available as a niobium-doped and therefore conducting substrate material. Thus, one has an ideal substrate for the growth of the dielectric layer in conjunction with a substrate which acts as gate electrode. As the organic semiconductor the small molecules pentacene and copper phthalocyanine (CuPc) were sublimated, as electrical contacts gold was used. As a key part of this work an ultra high vacuum chamber system was constructed for in situ preparation of field effect transistors. For the deposition of the organic thin films a molecular beam deposition chamber was built, including a manipulator and effusion cells as evaporation sources. For the preparation of the dielectric a sputtering chamber was set-up. Another chamber was used in conjunction with an effusion cell for the deposition of the gold contacts. For the structured deposition of the different layers in the devices a shadow mask system was implemented. Movable masks could be positioned by means of a wobble stick onto the sample carriers. The system thus allowed for the use of masks in all chambers. The different thin films required in the transistor structure were first individually prepared and characterized. For the characterization primarily X-ray diffraction and optical microscopy were used. The growth of pentacene was analyzed on aplha-AlO substrates. With X-ray diffraction the (00l) reflections of the thin film phase were observed. In growth studies of CuPc aplha-AlO and STO substrates were used. With X-ray diffraction the aplha-phase was detected. With increasing substrate temperature an increase in crystallinity, but also an increase in surface roughness was observed. The sputtering of STO as a high-k dielectric was studied and optimized. Simultaneously, a high deposition rate, a smooth film surface and good crystallinity of the layer were required. As the most important parameters the substrate temperature, pressure and sputtering power were identified. Argon and oxygen were employed as sputtering gases, as substrate MgO was used. The films showed in comparison to crystalline STO a distortion to larger lattice constants. The degree of distortion decreased with increasing chamber pressure, on the other hand, deposition rate decreased with increasing chamber pressure as well. By combining the individual deposition processes FETs in bottom-gate geometry were prepared. The first step was always sputtering of the STO dielectric on niobium-doped STO substrates. Subsequently, the electrodes and the organic layer were deposited. For comparison transistors on silicon substrates with silicon dioxide (SiO2) as the dielectric were prepared. To study the transistor properties a measurement setup was build. A dielectric constant of about 190 for the STO in the transistors was achieved. The transistors with CuPc as active layer showed p-type conduction behavior. The transistors with STO as dielectric had a much stronger response than those with SiO2. They reached mobilities of 2E-4 cm2/Vs at very low applied voltages of 3V. It could thus be demonstrated that STO is suitable as a dielectric for organic FETs, and that through the use of high-k dielectrics high charge carrier densities can be achieved.
Next-generation DIRC detectors, like the PANDA Barrel DIRC, with improved optical designs and better spatial and timing resolution, require correspondingly advanced reconstruction and PID methods. The investigation of the PID performance of two DIRC counters and the evaluation of the reconstruction and PID algorithms form the core of this thesis. Several reconstruction and PID approaches were developed, optimized, and tested using hadronic beam particles, experimental physics events, and Geant simulations. The near-final design of the PANDA Barrel DIRC was evaluated with a prototype in the T9 beamline at CERN in 2018. The analysis finds excellent agreement between the experimental data and the Geant simulations for all reconstruction algorithms. The best PID performance of up to $5.2 \pm 0.2$ s.d. $\pi$/K separation at 3.5 GeV/c, was obtained with a time imaging PID method. The PANDA Barrel DIRC simulation, as well as the reconstruction and PID algorithms, were evaluated using experimental data from the GlueX DIRC as part of the FAIR Phase-0 program. The performance validation was carried out using physics events of the GlueX experiment and simulations. The initial analysis results of the commissioning dataset show a $\pi$/K separation power of up to 3 s.d. at a momentum of 3.0-3.5 GeV/c, obtained using a geometric reconstruction algorithm.
Conclusion Scale Integration Based on the results of spike-field coherence, the underlying process of shortterm memory seems to involve networks of different sizes within and, most probably, beyond prefrontal cortex. Spikes, which were generated by single neurons, cooperate with local field potentials, which were the slower fluctuations of the environment. Although differences among behavioral conditions appear to be based on rather few instances of phase-locked spikes, the task-related effects on spike-field coherence are highly reliable and cannot be explained by chance, as the comparison of results from experimental and simulated data shows. The differential locking of prefrontal neuron populations with two different frequency bands in their input signals suggests that neuronal activity underlying short-term memory in prefrontal cortex transiently engages cortical circuits on different spatial scales, probably in order to coordinate distributed processes. NeuroXidence method and Synchronizedfiring Based on the results of the calibration datasets, for bi- and multi-variate cases, the extension of NeuroXidence remains its sensitivity and reliability of detecting coordinate firing events for different processes. Based on this extension of NeuroXidence, we demonstrated that in monkey’s prefrontal cortex during short-term memory task, encoding and maintenance of the information rely on the formation of neuronal assemblies characterized by precise and reliable synchronization of spiking activity on a millisecond time scale, which is consistent with the results from spike-spike coherence. The task and performance dependent modulation of synchrony reflects the dynamic formation of group of neurons has large effect on short-term-memory.
Nanocarbon structures, such as fullerenes and nanotubes, have generated considerable interest and research, due to their unique properties and potential applications. In this thesis, we present a study of the phase transition properties of nanocarbon clusters,in particular, we pay special consideration to fullerenes. The work presented in this thesis is largely theoretical and computational in nature, employing as a tool, molecular dynamics simulations to probe the dynamic stability of fullerenes and associated nanocarbon structures such as graphenes and nanotubes.
In this work we investigate phenomenological aspects of an anisotropic quark-gluon plasma. In the first part of this thesis, we formulate phenomenologicalmodels that take into account the momentumspace anisotropy of the system developed during the expansion of the fireball at early-times. By including the proper-time dependence of the parton hard momentum scale, phard(), and the plasma anisotropy parameter, Xi, the proposed models allow us to interpolate from 0+1 pre-equilibrated expansion at early-times to 0+1 ideal hydrodynamics at late times. We study dilepton production as a valuable observable to experimentally determine the isotropization time of the system as well as the degree of anisotropy developed at early-times. We generalize our interpolating models to include the rapidity dependence of phard and consider its impact on forward dileptons. Next, we discuss how to constrain the onset of hydrodynamics by demanding two requirements of the solutions to the equations of motion of viscous hydrodynamics. We show this explicitly for 0+1 dimensional 2nd-order conformal viscous hydrodynamics and find that the initial conditions are non-trivially constrained. Finally, we demonstrate how to match the initial conditions for 0+1 dimensional viscous hydrodynamics from pre-equilibrated expansion. We analyze the dependence of the entropy production on the pre-equilibrium phase and discuss limitations of the standard definitions of the non-equilibrium entropy in kinetic theory.
Within this thesis, an experimental study of the photo double ionization (PDI) and the simultaneous ionization-excitation is performed for lithium in different initial states Li (1s22l) (l = s, p). The excess energy of the linearly polarized VUV-light is between 4 and 12 eV above the PDI-threshold. Three forefront technologies are combined: a magneto-optical trap (MOT) for lithium generating an ultra-cold and, by means of optical pumping, a state-prepared target; a reaction microscope (ReMi), enabling the momentum resolved detection of all reaction fragments with high-resolution and the free-electron laser in Hamburg (FLASH), providing an unprecedented brilliant photon beam at favourable time structure to access small cross sections. Close to threshold the total as well as differential PDI cross sections are observed to critically depend on the excitation level and the symmetry of the initial state. For the excited state Li (1s22p) the PDI dynamics strongly depends on the alignment of the 2p-orbital with respect to the VUV-light polarization and, thus, from the population of the magnetic substates (mp = 0, ±1). This alignment sensitivity decreases for increasing excess energy and is completely absent for ionization-excitation. Time-dependent close-coupling calculations are able to reproduce the experimental total cross sections with deviations of at most 30%. All the experimental observations can be consistently understood in terms of the long range electron correlation among the continuum electrons which gives rise to their preferential back-to-back emission. This alignment effect, which is observed here for the first time, allows controlling the PDI dynamics through a purely geometrical modification of the target initial state without changing its internal energy.
In der vorliegenden Arbeit wird die Photodoppelionisation (PDI) von Helium (He) experimentell untersucht. Dazu wurde an der Synchrotronstrahlenquelle Advanced Light Source des Lawrence Berkeley National Laboratory (USA) der vollständig differentielle Wirkungsquerschnitt (FDCS) der PDI von He mit linear sowie mit links und rechts zirkular polarisiertem Licht bei den zwei Photon-Energien E_gamma = 179 eV und 529 eV gemessen. Dabei gelang erstmals eine Messung, bei der die Kontinuumsenergie der Fragmente wesentlich über der Bindungsenergie (79 eV) des Systems liegt. Aufgrund dieser hohen Energie lassen die gemessenen Winkel- und Energieverteilungen erstmals Rückschlüsse auf die Wechselwirkungsprozesse in der Ionisation zu. In allen bisherigen Messungen bei niedrigen Photon-Energien überdeckt der Einfluß der Elektron-Elektron-Wechselwirkung im Endzustand alle Spuren der seit langem theoretisch diskutierten Reaktionsmechanismen. Der FDCS der PDI von He wurde mit einer COLTRIMS (COLd Target Recoil Ion Momentum Spectroscopy)-Apparatur gemessen. Hierbei wird das Gastarget durch eine adiabatische Expansion gekühlt und dann mit dem Photon-Strahl zum Überlapp gebracht. Die bei einer Reaktion freigesetzten Elektronen, deren Summenenergie sich zu E_sum = E_1 + E_2 = E_gamma - 79 eV berechnet (die Summenenergie der beiden Elektronen ist gleich der Überschußenergie E_exc), werden mit einer Energie bis zu E_1,2 = 60 eV durch ein elektrisches und magnetisches Feld im vollen Raumwinkel von 4 pi auf einem großen ortssensitiven Detektor abgebildet. Das elektrische Feld projiziert die kalten Rückstoßionen auf einen zweiten ortssensitiven Detektor. Aus der Flugzeit und dem Auftreffort werden der Ladungszustand und der Impuls der Teilchen ermittelt. Ergebnisse: Die Energieaufteilung auf die beiden Elektronen erfolgt asymmetrisch. Diese Asymmetrie ist bei der PDI 450 eV über der Doppelionisationsschwelle (79 eV) stärker ausgeprägt als bei E_exc = 100 eV. Langsame Elektronen werden generell isotrop zur Polarisation emittiert (beta = 0), während die 100 eV-Elektronen einen Anisotropie-Parameter von beta = 1,7 und die sehr schnellen 450 eV-Elektronen sogar eine Dipolverteilung (beta = 2) bzgl. der Polarisationsachse aufweisen. Eine asymmetrische Energieaufteilung zusammen mit einem Anisotropie-Parameter von beta = 2 für die 450 eV-Elektronen zeigt, daß bei der PDI 450 eV über der Schwelle ein Zwei-Stufen-Prozeß vorliegt, in dem das erste Elektron die Energie und den Drehimpuls des Photons aufnimmt. Das zweite Elektron gelangt dann durch den Shake-off oder den Two-Step-One-Mechanismus ins Kontinuum. Sowohl die Häufigkeitsverteilung der Zwischenwinkel der Elektronen als auch der Verlauf der Quadrate der geraden und der ungeraden Amplituden bei der PDI 450 eV über der Schwelle zeigen, daß sehr langsame Elektronen (2 eV) hauptsächlich durch den Shake-off-Mechanismus ins Kontinuum gelangen, während etwas schnellere 30 eV-Elektronen ihre Energie über einen (e,2e)-Stoß (Two-Step-One-Mechanismus) erhalten. Für 100 eV über der Schwelle zeigt sich, daß der Relativimpulsvektor der beiden Elektronen parallel zum Polarisationsvektor steht. Das bedeutet, daß die PDI von He 100 eV über der Schwelle nicht mehr im Gültigkeitsbereich der Wannier-Näherung liegt. Aufgrund der großen Geschwindigkeitsdifferenzen kann die PDI von Helium parallel zum Polarisationsvektor erfolgen. Der gegen den Zwischenwinkel varphi_12 der Elektronen aufgetragene normierte Zirkulare Dichroismus CD_n ist bei E_exc = 100 eV wesentlich stärker ausgeprägt als bei E_exc = 450 eV. Der Wert des Extremums ist für alle Energieaufteilungen - außer der symmetrischen - gleich. Für beide Überschußenergien findet man eine Abhängigkeit der varphi_12-Position des Extremums von der Energieaufteilung. Die Extreme entfernen sich mit zunehmender asymmetrischer Energieaufteilung von varphi_12=180°. Die experimentell gewonnenen Ergebnisse zu den vollständig differentiellen Wirkungsquerschnitten der PDI von He sowohl mit linear als auch mit links und rechts zirkular polarisiertem Licht bei 100 eV und 450 eV über der Doppelionisationsschwelle zeigen insgesamt gute Übereinstimmungen mit den Ergebnissen der convergent-close-coupling-Rechnungen von A. Kheifets und I. Bray.
Die vorliegende Arbeit bietet zunächst einen weiteren Beweis für die Existenz des neutralen Heliumdimers. Darüber hinaus konnten zwei verschiedene Prozesse identifiziert werden, über die die Absorbtion eines Photons zur Ionisation beider Atome des Dimers über sehr große Abstände führen kann. Oberhalb einer Photonenenergie von 65,4 eV konnte ein ICD Prozess beobachtet werden, der über Photoionisation mit gleichzeitiger Anregung von einem der beiden Atome realisiert wird. Bei 77,86 eV konnte ICD über elektronisch angeregte Zustände bis n=6 nachgewiesen werden. In der KER-Verteilung konnten zudem Strukturen gefunden werden, die auf Vibrationsanregungen im Zwischenzustand des Dimer-Ions schließen lassen. Eine vollständig quantenmechanische Rechnung von Sisourat et al. konnte dies schließlich hervorragend bestätigen. Es konnte also ein direkter Blick auf die Vibrationswellenfunktionen des Systems erlangt werden. In anderen Systemen ist dies in der Regel nicht möglich, da sich alle Zustände üblicherweise zu einer strukturlosen Verteilung überlagern. Weiterhin konnte gezeigt werden, dass sich die Winkelverteilungen von ICD- und Photoelektronen in verschiedenen Bereichen des KER mitunter stark voneinander unterscheiden. Dies konnte auf die unterschiedliche Besetzung von verschiedenen Potentialkurven zurückgeführt werden. Unterhalb der Photonenenergieschwelle zur Anregung und Ionisation eines Heliumatoms konnte ein weiterer, zweistufiger Ionisationsmechanismus gefunden werden. Hier wird zunächst durch Photoionisation ein Elektron aus einem der beiden Atome im Dimer freigesetzt. Dieses Photoelektron kann nun am neutralen Atom gestreut werden und dabei ausreichend viel Energie übertragen, um dieses ebenfalls zu ionisieren. Es konnte gezeigt werden, dass der Prozess einer Abhängigkeit von der Polarisation der Synchrotronstrahlung unterliegt, die man für Photoionisation erwarten würde. Die Energie- und Winkelverteilungen der Elektronen konnten daher mit vorangegangenen Elektronenstoß-Experimenten verglichen werden. Die gute Übereinstimmung mit diesen Daten rechtfertigt eine anschauliche Sichtweise des Prozesses als Analogon zum klassischen Billiard-Stoß. Der Two-Step-Prozess wurde bisher zwar schon in vielen Systemen als theoretisches Modell zur Doppelionisation beschrieben, allerdings konnten die einzelnen Unterprozesse bisher nicht gesondert gemessen werden. Die großen Abstände im Heliumdimer ermöglichen erstmals eine deutliche Trennung in Photoionisation an einem Atom und Elektronenstoß (e,2e) am Nachbaratom. Der Two-Step-Prozess konnte außerdem dazu verwendet werden, die ungewöhnliche Grundzustandswellenfunktion des Heliumdimers zu experimentell zu bestätigen. Eine Analyse des gemessenen KER konnte dabei deutliche Abweichungen zu einer klassischen Theorie aufzeigen. Erst eine vollständig quantenmechanische Rechnung des Übergangs von Sisourat et al. konnte die Messdaten beschreiben.
Im Rahmen dieser Dissertation wurde die Photophysik und die elektronische Struktur einer Klasse neuartiger Donator-Akzeptor-Ladungstransfer-Komplexe untersucht. Im Wesentlichen bestehen diese Verbindungen aus einem Ferrocen-Donator (Fc) und organischen Akzeptoren, die über B-N-Bindungen verbrückt sind, welche sich bei dieser Art von makromolekularen Systemen spontan bilden. Zentraler Gegenstand dieser Arbeit war die spektroskopische Untersuchung des Metall-zu-Ligand-Ladungstransfers (engl. Abkürzung: MLCT) im elektronischen Anregungszustand dieser kationischen Komplexverbindungen, die im Weiteren als „Fc-B-bpy“-Verbindungen bezeichnet werden. Die vorliegende Arbeit analysiert eine Vielzahl miteinander verwandter Fc-B-bpy-Derivate. Die Arbeit ist gegliedert in 1.) die Analyse der Absorptionsspektren vom UV- bis zum nahen Infrarot-Spektralbereich (250-1000 nm) von Lösungen, dotierten Polymer-Dünnfilmen und Einkristallen, 2.) die zeitaufgelöste optische Spektroskopie des angeregten Zustands auf der Pikosekunden-Zeitskala, 3.) die Analyse elektrochemischer Messungen an Lösungen, und 4.) die Auswertung quantenchemischer Berechnungen. Für die zeitaufgelösten Messungen wurde ein komplexes optisches Spektroskopie-System mit breitbandigen Femtosekunden-Pulsen sowie den entsprechenden zeitaufgelösten Detektionsmethoden (spektral gefilterte Weißlicht-Detektion) aufgebaut. Die Ergebnisse dieser Arbeit beweisen die Existenz eines MLCT-Übergangs mit fast vollständigem Übergang eines Fc-Donator-Elektrons zum B-bpy-Akzeptor bei optischer Anregung. Die vergleichenden Untersuchungen der spektroskopischen Eigenschaften verschiedener Derivate liefern wichtige Information für die Entwicklung neuartiger Derivate, einschließlich verwandter Polymere, mit verbesserten spektroskopischen Eigenschaften. Es wurden transiente Absorptionsmessungen bestimmter Fc-B-bpy-Derivate in Lösung nach gepulster Anregung der MLCT-Bande (bei 500 nm) über einen Zeitbereich von 0,1-1000 ps und einen Wellenlängenbereich von 460-760 nm vorgenommen. Aus den Messergebnissen geht hervor, dass die Relaxation aus dem angeregten MLCT-Zustand in den Grundzustand auf verschiedenen Zeitskalen geschehen kann, welche im Bereich zwischen ~18 und 900 ps liegen. Ein Vergleich verschiedener Derivate mit unterschiedlicher Flexibilität in der Konformation zeigt, dass die Starrheit der Bindungen zwischen Donatoren und Akzeptoren ein wesentlicher Faktor für die Lebensdauer des angeregten Zustands ist. Wenn die Akzeptorgruppen relativ frei rotieren können, ist es der Verbindung möglich, eine Geometrie einzunehmen, von der aus ein effizienter, strahlungsfreier Übergang in den Grundzustand erfolgen kann. Dieser Befund zeigt einen Weg auf, wie neuartige, verwandte Verbindungen mit größerer Lebensdauer das angeregten Zustands synthetisiert werden können, indem darauf geachtet wird, daß eine starre molekulare Architektur zwischen Donator und Akzeptor verwirklicht wird.