620 Ingenieurwissenschaften und zugeordnete Tätigkeiten
Refine
Document Type
- Article (14)
- Doctoral Thesis (1)
Has Fulltext
- yes (15)
Is part of the Bibliography
- no (15)
Keywords
Institute
- Physik (15) (remove)
Understanding the physics of strongly correlated electronic systems has been a central issue in condensed matter physics for decades. In transition metal oxides, strong correlations characteristic of narrow d bands are at the origin of remarkable properties such as the opening of Mott gap, enhanced effective mass, and anomalous vibronic coupling, to mention a few. SrVO3 with V4+ in a 3d1 electronic configuration is the simplest example of a 3D correlated metallic electronic system. Here, the authors' focus on the observation of a (roughly) quadratic temperature dependence of the inverse electron mobility of this seemingly simple system, which is an intriguing property shared by other metallic oxides. The systematic analysis of electronic transport in SrVO3 thin films discloses the limitations of the simplest picture of e–e correlations in a Fermi liquid (FL); instead, it is shown show that the quasi-2D topology of the Fermi surface (FS) and a strong electron–phonon coupling, contributing to dress carriers with a phonon cloud, play a pivotal role on the reported electron spectroscopic, optical, thermodynamic, and transport data. The picture that emerges is not restricted to SrVO3 but can be shared with other 3d and 4d metallic oxides.
High shares of intermittent renewable power generation in a European electricity system will require flexible backup power generation on the dominant diurnal, synoptic, and seasonal weather timescales. The same three timescales are already covered by today’s dispatchable electricity generation facilities, which are able to follow the typical load variations on the intra-day, intra-week, and seasonal timescales. This work aims to quantify the changing demand for those three backup flexibility classes in emerging large-scale electricity systems, as they transform from low to high shares of variable renewable power generation. A weather-driven modelling is used, which aggregates eight years of wind and solar power generation data as well as load data over Germany and Europe, and splits the backup system required to cover the residual load into three flexibility classes distinguished by their respective maximum rates of change of power output. This modelling shows that the slowly flexible backup system is dominant at low renewable shares, but its optimized capacity decreases and drops close to zero once the average renewable power generation exceeds 50% of the mean load. The medium flexible backup capacities increase for modest renewable shares, peak at around a 40% renewable share, and then continuously decrease to almost zero once the average renewable power generation becomes larger than 100% of the mean load. The dispatch capacity of the highly flexible backup system becomes dominant for renewable shares beyond 50%, and reach their maximum around a 70% renewable share. For renewable shares above 70% the highly flexible backup capacity in Germany remains at its maximum, whereas it decreases again for Europe. This indicates that for highly renewable large-scale electricity systems the total required backup capacity can only be reduced if countries share their excess generation and backup power.
The transition to a future electricity system based primarily on wind and solar PV is examined for all regions in the contiguous US. We present optimized pathways for the build-up of wind and solar power for least backup energy needs as well as for least cost obtained with a simplified, lightweight model based on long-term high resolution weather-determined generation data. In the absence of storage, the pathway which achieves the best match of generation and load, thus resulting in the least backup energy requirements, generally favors a combination of both technologies, with a wind/solar PV (photovoltaics) energy mix of about 80/20 in a fully renewable scenario. The least cost development is seen to start with 100% of the technology with the lowest average generation costs first, but with increasing renewable installations, economically unfavorable excess generation pushes it toward the minimal backup pathway. Surplus generation and the entailed costs can be reduced significantly by combining wind and solar power, and/or absorbing excess generation, for example with storage or transmission, or by coupling the electricity system to other energy sectors.
This work aims at radar sensors in the frequency band from 57 to 64 GHz that can be embedded in wind turbine blades during manufacturing, enabling non-destructive quality inspection directly after production and structural health monitoring (SHM) during the complete service life of the blade. In this paper, we show the fundamental damage detection capability of this sensor technology during fatigue testing of typical rotor blade materials. Therefore, a frequency modulated continuous wave (FMCW) radar sensor is used for damage diagnostics, and the results are validated by simultaneous camera recordings. Here, we focus on the failure modes delamination, fiber waviness (ondulation), and inter-fiber failure. For each failure mode, three samples have been designed and experimentally investigated during fatigue testing. A damage index has been proposed based on residual, that is, differential, signals exploiting measurements from pristine structural conditions. This study shows that the proposed innovative radar approach is able to detect continuous structural degradation for all failure modes by means of gradual signal changes.
This study presents an ultra-wideband, elliptical slot, planar monopole antenna for early breast cancer microwave imaging. The on-body antenna's operation is optimised by direct contact with the patient's skin. With a compact size of 9 × 7 mm, the antenna covers a wide bandwidth from 16 to 24 GHz for reflection coefficients lower than –10 dB. Besides, it also features an electrode for electrical impedance tomography applications. Verification on a volunteer's breast gives an excellent agreement with the simulation for the defined bandwidth. Furthermore, as the first stage of the system's characterisation, pork fat is also used to demonstrate the possibility to enhance the transmission between the antennas within the high loss environment. Those results propose the feasibility of implementing a high-frequency radar system for breast cancer detection.
Consequences of minimal length discretization on line element, metric tensor, and geodesic equation
(2021)
When minimal length uncertainty emerging from a generalized uncertainty principle (GUP) is thoughtfully implemented, it is of great interest to consider its impacts on gravitational Einstein field equations (gEFEs) and to try to assess consequential modifications in metric manifesting properties of quantum geometry due to quantum gravity. GUP takes into account the gravitational impacts on the noncommutation relations of length (distance) and momentum operators or time and energy operators and so on. On the other hand, gEFE relates classical geometry or general relativity gravity to the energy–momentum tensors, that is, proposing quantum equations of state. Despite the technical difficulties, we intend to insert GUP into the metric tensor so that the line element and the geodesic equation in flat and curved space are accordingly modified. The latter apparently encompasses acceleration, jerk, and snap (jounce) of a particle in the quasi-quantized gravitational field. Finite higher orders of acceleration apparently manifest phenomena such as accelerating expansion and transitions between different radii of curvature and so on.
This paper explores the many interesting implications for oscillator design, with optimized phase-noise performance, deriving from a newly proposed model based on the concept of oscillator conjugacy. For the case of 2-D (planar) oscillators, the model prominently predicts that only circuits producing a perfectly symmetric steady-state can have zero amplitude-to-phase (AM-PM) noise conversion, a so-called zero-state. Simulations on standard industry oscillator circuits verify all model predictions and, however, also show that these circuit classes cannot attain zero-states except in special limit-cases which are not practically relevant. Guided by the newly acquired design rules, we describe the synthesis of a novel 2-D reduced-order LC oscillator circuit which achieves several zero-states while operating at realistic output power levels. The potential future application of this developed theoretical framework for implementation of numerical algorithms aimed at optimizing oscillator phase-noise performance is briefly discussed.
Nano-granular metals are materials that fall into the general class of granular electronic systems in which the interplay of electronic correlations, disorder and finite size effects can be studied. The charge transport in nano-granular metals is dominated by thermally-assisted, sequential and correlated tunneling over a temperature-dependent number of metallic grains. Here we study the frequency-dependent conductivity (AC conductivity) of nano-granular Platinum with Pt nano-grains embedded into amorphous carbon (C). We focus on the transport regime on the insulating side of the insulator metal transition reflected by a set of samples covering a range of tunnel-coupling strengths. In this transport regime polarization contributions to the AC conductivity are small and correlation effects in the transport of free charges are expected to be particularly pronounced. We find a universal behavior in the frequency dependence that can be traced back to the temperature-dependent zero-frequency conductivity (DC conductivity) of Pt/C within a simple lumped-circuit analysis. Our results are in contradistinction to previous work on nano-granular Pd/ZrO2ZrO2 in the very weak coupling regime where polarization contributions to the AC conductivity dominated. We describe possible future applications of nano-granular metals in proximity impedance spectroscopy of dielectric materials.
In this roadmap article, we have focused on the most recent advances in terahertz (THz) imaging with particular attention paid to the optimization and miniaturization of the THz imaging systems. Such systems entail enhanced functionality, reduced power consumption, and increased convenience, thus being geared toward the implementation of THz imaging systems in real operational conditions. The article will touch upon the advanced solid-state-based THz imaging systems, including room temperature THz sensors and arrays, as well as their on-chip integration with diffractive THz optical components. We will cover the current-state of compact room temperature THz emission sources, both optolectronic and electrically driven; particular emphasis is attributed to the beam-forming role in THz imaging, THz holography and spatial filtering, THz nano-imaging, and computational imaging. A number of advanced THz techniques, such as light-field THz imaging, homodyne spectroscopy, and phase sensitive spectrometry, THz modulated continuous wave imaging, room temperature THz frequency combs, and passive THz imaging, as well as the use of artificial intelligence in THz data processing and optics development, will be reviewed. This roadmap presents a structured snapshot of current advances in THz imaging as of 2021 and provides an opinion on contemporary scientific and technological challenges in this field, as well as extrapolations of possible further evolution in THz imaging.
Surface plasmon polaritons on (silver) nanowires are promising components for future photonic technologies. Here, we study near-field patterns on silver nanowires with a scattering-type scanning near-field optical microscope that enables the direct mapping of surface waves. We analyze the spatial pattern of the plasmon signatures for different excitation geometries and polarization and observe a plasmon wave pattern that is canted relative to the nanowire axis, which we show is due to a superposition of two different plasmon modes, as supported by electromagnetic simulations including the influence of the substrate. These findings yield new insights into the excitation and propagation of plasmon polaritons for applications in nanoplasmonic devices.
In power systems, flow allocation (FA) methods enable to allocate the usage and costs of the transmission grid to each single market participant. Based on predefined assumptions, the power flow is split into isolated generator-specific or producer-specific sub-flows. Two prominent FA methods, Marginal Participation (MP) and Equivalent Bilateral Exchanges (EBEs), build upon the linearized power flow and thus on the Power Transfer Distribution Factors (PTDFs). Despite their intuitive and computationally efficient concepts, they are restricted to networks with passive transmission elements only. As soon as a significant number of controllable transmission elements, such as high-voltage direct current (HVDC) lines, operate in the system, they lose their applicability. This work reformulates the two methods in terms of Virtual Injection Patterns (VIPs), which allows one to efficiently introduce a shift parameter q to tune contributions of net sources and net sinks in the network. In this work, major properties and differences in the methods are pointed out, and it is shown how the MP and EBE algorithms can be applied to generic meshed AC-DC electricity grids: by introducing a pseudo-impedance ω¯ , which reflects the operational state of controllable elements and allows one to extend the PTDF matrix under the assumption of knowing the current flow in the system. Basic properties from graph theory are used to solve for the pseudo-impedance in dependence of the position within the network. This directly enables, e.g., HVDC lines to be considered in the MP and EBE algorithms. The extended methods are applied to a low-carbon European network model (PyPSA-EUR) with a spatial resolution of 181 nodes and an 18% transmission expansion compared to today’s total transmission capacity volume. The allocations of MP and EBE show that countries with high wind potentials profit most from the transmission grid expansion. Based on the average usage of transmission system expansion, a method of distributing operational and capital expenditures is proposed. In addition, it is shown how injections from renewable resources strongly drive country-to-country allocations and thus cross-border electricity flows.
We present experimental results and theoretical simulations of the adsorption behavior of the metal–organic precursor Co2(CO)8 on SiO2 surfaces after application of two different pretreatment steps, namely by air plasma cleaning or a focused electron beam pre-irradiation. We observe a spontaneous dissociation of the precursor molecules as well as autodeposition of cobalt on the pretreated SiO2 surfaces. We also find that the differences in metal content and relative stability of these deposits depend on the pretreatment conditions of the substrate. Transport measurements of these deposits are also presented. We are led to assume that the degree of passivation of the SiO2 surface by hydroxyl groups is an important controlling factor in the dissociation process. Our calculations of various slab settings, using dispersion-corrected density functional theory, support this assumption. We observe physisorption of the precursor molecule on a fully hydroxylated SiO2 surface (untreated surface) and chemisorption on a partially hydroxylated SiO2 surface (pretreated surface) with a spontaneous dissociation of the precursor molecule. In view of these calculations, we discuss the origin of this dissociation and the subsequent autocatalysis.
The biological effects of energetic heavy ions are attracting increasing interest for their applications in cancer therapy and protection against space radiation. The cascade of events leading to cell death or late effects starts from stochastic energy deposition on the nanometer scale and the corresponding lesions in biological molecules, primarily DNA. We have developed experimental techniques to visualize DNA nanolesions induced by heavy ions. Nanolesions appear in cells as “streaks” which can be visualized by using different DNA repair markers. We have studied the kinetics of repair of these “streaks” also with respect to the chromatin conformation. Initial steps in the modeling of the energy deposition patterns at the micrometer and nanometer scale were made with MCHIT and TRAX models, respectively.
Im Rahmen dieser Arbeit wurde untersucht, inwieweit eine Bewegungsschärzung aus monokularen Bildsequenzen von Straßenverkehrsszenen und eine darauf aufbauende Hinderniserkennung mit Hilfe von statistischen oder neuronalen Methoden realisiert werden kann. Bei dem zugrunde liegenden mathematischen Modell wird angenommen, daß die Umgebung, in der sich ein Fahrzeug bewegt, im wesentlichen eben ist, was für Verkehrsequenzen in guter Näherung erfüllt ist. Im ersten Teil dieser Arbeit wurde ein statistisches Verfahren zur Bewegungsschätzung vorgestellt und diskutiert. Der erste Schritt dieses Verfahrens stellt die Generierung eines sogenannten Markantheitsbildes dar, in welchem Objektkanten und Objektecken visuell hervorgehoben werden. Für die daraus resultierende Liste von markanten Bildbereichen werden anschließend unter Verwendung einer sogenannten Verschiebungsvektorschätzung, Korrespondenzen im zeitlich folgenden Bild ermittelt. Ausgehend von dem resultierenden Verschiebungsvektorfeld, werden in dem nächsten Schritt des Verfahrens die Bewegungsgrößen ermittelt, also die Rotationsmatrix und der Translationsvektor des Fahrzeugs, beziehungsweise der Kamera. Um abschließend eine Hinderniserkennung realisieren zu können, erfolgt unter Verwendung der Bewegungsgrößen eine Bewegungskompensation der Bilddaten. Bei einer solchen Bewegungskompensation wird unter Verwendung der ermittelten Bewegungsgrößen und dem Modell der bewegten Ebene eine Rücktransformation jedes Bildpixels durchgeführt, so daß bei der Bildung eines Differenzbildes zwischen dem bewegungskompensierten Bild und dem tatsächlich aufgenommenen Bild, dreidimensionale Strukturen, die ja das Ebenenmodell verletzen, deutlich hervortreten und somit auf potentielle Hindernisse hinweisen. Es hat sich gezeigt, daß Fehlmessungen in den Verschiebungsvektoren, welche beispielsweise durch periodische Strukturen auf der Ebene auftreten können, die Bewegungsschätzung und die Hinderniserkennung empfindlich stören. Diese statistischen Ausreißer bewirken, daß trotz der Verwendung von robusten Schätzmethoden, eine stabile Hinderniserkennung nur durch die Einbeziehung von Vorwissen über die Art der Bewegung des Fahrzeugs realisiert werden kann. Weiterhin führen die Komplexität des Verfahrens und die damit verbundenen hohen Anforderungen an die Rechenleistung der eingesetzten Hardware dazu, daß die für die praktische Anwendbarkeit so wichtige Echtzeitfähigkeit des Verfahrens bisher nur für Eingangsbilder mit geringer Auflösung ermöglicht werden konnte. Speziell für die Bildverarbeitung hat sich das neue Paradigma der Zellularen Neuronalen Netzwerke als außerordentlich leistungsfähig erwiesen. Neben der extrem hohen Verarbeitungsgeschwindigkeit von CNN-basierten schaltungstechnischen Realisierungen zeichnen sie sich durch eine hohe Robustheit bei vertauschten oder fehlerhaften Eingangsdaten aus. Für nahezu jedes aktuelle Problem der Bildverarbeitung wurde bisher ein geeignetes CNN bestimmt. Auch für komplexe Aufgabenstellungen aus der Bildverarbeitung, wie beispielsweise die Texturklassifikation, die Spurverfolgung oder die Gewinnung von Tiefeninformation konnten bereits CNN-Programme implementiert und schaltungstechnisch verwirklicht werden. So konnte auch im zweiten Teil dieser Arbeit gezeigt werden, daß die einzelnen Schritte der Hinderniserkennung aus monokularen Bildsequenzen ebenfalls unter Verwendung eines CNN realisierbar sind. Es wurde demonstriert, daß für die Generierung eines Markantheitsbildes bereits ein Standard-CNN mit linearer Kopplungsfunktion und der Nachbarschaft r=1 verwendet werden kann. Das rechenaufwändige statistische Verfahren der Markantheitsbildberechnung kann somit durch einen einzigen CNN-Verarbeitungsschritt durchgeführt werden. Weiterhin wurde im Rahmen dieser Arbeit gezeigt, daß auch der folgende, rechenintensive Schritt des statistischen Verfahrens der Hinderniserkennung, nämlich die Verschiebungsvektorschätzung, mittels CNN verwirklicht werden kann. Hierzu sind CNN mit polynomialen Kopplungsfunktionen und der Nachbarschaft r=1 notwendig. Bei den durchgeführten Untersuchungen hat sich herausgestellt, daß die CNN-basierten Verarbeitungsschritte den statistischen Methoden in den Punkten Robustheit und Verarbeitungsgeschwindigkeit deutlich überlegen sind. Abschließend wurde in dieser Arbeit gezeigt, daß mit Hilfe von CNN sogar eine direkte Hinderniserkennung aus monokularen Bildsequenzen - ohne den Umweg über die Bestimmung der Verschiebungsvektoren und der Bewegungsgrößen - realisiert werden kann. In dem vorgestellten Verfahren wird nach zwei Vorverarbeitungsschritten, die Hinderniserkennung in einem einzigen Schritt unter Verwendung eines CNN mit polynomialen Zellkopplungsgewichten vom Grade D=3 und der Nachbarschaft r=2 durchgeführt. Das vorgeschlagene Verfahren führt zu einer wesentlichen Vereinfachung der Hinderniserkennung in monokularen Bildsequenzen, da die Bewegegungsschätzung aus dem statistischen Verfahren nicht länger notwendig ist. Die Umgehung der expliziten Bewegungsschätzung hat weiterhin den Vorteil, daß der Rechenaufwand stark reduziert wurde und durch den Wegfall der Verschiebungsvektorschätzung und dem damit verketteten Problem der Ausreißer, ist das vorgestellte CNN-basierte Verfahren außerdem sehr robust. Die ersten Resultate, die unter Verwendung von synthetischen und natürlichen Bildsequenzen erhalten wurden, sind überaus vielversprechend und zeigen, daß CNN ausgezeichnet zur Verarbeitung von Videosequenzen geeignet sind.