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Herzfehler sind weltweit die häufigste Form von angeborenen Organdefekten. In unterschiedlichen Studien wird die Inzidenz zumeist zwischen vier und elf von 1.000 Lebendgeburten angegeben (1–5). Im Rahmen der multizentrischen PAN-Studie (PAN: Prävalenz angeborener Herzfehler bei Neugeborenen), welche die Häufigkeit angeborener Herzfehler bei Neugeborenen in Deutschland zwischen Juli 2006 und Juni 2007 untersuchte, ergab sich eine Gesamtprävalenz von 107,6 pro 10.000 Lebendgeburten. Gegenstand dieser Arbeit sind Untersuchungen an Implantaten zur Behandlung von Atriumseptumdefekten (ASD). Vorhofseptumdefekte machen mit 17,0%, nach den Ventrikelseptumdefekten (VSD) mit 48,9%die zweithäufigste Art von Herzfehlern aus (6, 7).Als Vorhofseptumdefekte werden Öffnungen in der Scheidewand zwischen den Herzvorhöfen bezeichnet. Bei der Therapie eines ASD ist der minimalinvasive Verschluss mittels sogenannter Okkluder heute das Mittel der Wahl. Diese werden über einen femoralen Zugang im Rahmen einer Herzkatheteruntersuchung unter Ultraschallkontrolle und Durchleuchtung an die Implantationsstelle vorgeschoben und dort platziert(8). Die Okkluder bestehen in der Regel aus einem Drahtgeflecht aus Nitinol und haben die typische Form eines sogenannten Doppelschirmchens. Dabei weichen die unterschiedlichen Okkluder der einzelnen Firmen hinsichtlich Form und Beschaffenheit oft erheblich voneinander ab. Derzeit gibt es keine Untersuchungsmethode, die die auf dem Markt befindlichen Okkluder hinsichtlich ihrer mechanischen Eigenschaften vergleichbar macht. Diese Arbeit solleinen Beitrag erbringen, um grundlegende, die Okkludermodelle charakterisierende Parameter zu schaffen, um so deren interindividuelle Vergleichbarkeit zu ermöglichen. Hierzu werden in-vitro Messungen durchgeführt, welche geeignet sind das Verhalten der untersuchten Modelle unter unterschiedlichen Bedingungen und bei variierenden Defektgrößen zu charakterisieren.
With the increasing share of renewable energies and the nuclear phase-out, the energy transition is accelerating. From the perspective of building technology, there is great potential to support this transition given its large share in total energy consumption and the increasing number of flexible and controllable components and storages. However, a question often asked at the plant level is: "How do we use this flexibility to support the regional grid?". In this work, a grid-supportive controller of a real-world building energy plant was developed using mathematical optimisation methods and its technical feasibility was demonstrated. The results could convince actors from the energy industry and academia about the practicality of these methods and offer tools for their implementation.
Lithium-ion batteries play a vital role in a society more and more affected by the spectre of climate change: hence the need of lowering CO2 emissions and reducing the fossil fuel consumption. At the moment, lithium-ion batteries appear as the ideal candidates for this challenge but further research and development is required to understand their behaviour, predict their issues and therefore improve their performance. In this regard, mathematical modelling and numerical simulation have become standard techniques in lithium-ion battery research and development and have proven to be highly useful in supporting experimental work and increasing the predictability of model-based life expectancy.
This study focuses on the electrochemical ageing reactions at the anode, especially on the topic of lithium plating and its interaction with the solid electrolyte interface (SEI). The purpose of this work is a deeper understanding of these degradation processes through the construction of refined modelling frameworks and the analysis of simulations carried out over a wide range of operating conditions. The governing equations are implemented in the in-house multiphysics software package DENIS, while the electrochemistry model is based on the use of the open-source chemical kinetics code CANTERA.
The development, parameterisation and experimental validation of a comprehensive pseudo-three-dimensional multiphysics model of a commercial lithium-ion cell with blend cathode and graphite anode is presented. This model is able to describe and simulate both multiscale heat and mass transport and complex electrochemical reaction mechanisms, including also as extra feature the capability of reproducing a composite electrode where multiple active materials are subject to intercalation/deintercalation reaction.
A further extension to include reversible lithium plating process and predict ageing behaviour over a wide range of conditions, with a focus on the high currents and low temperatures particularly interesting for the fast charging topic, follows. This extended model is verified by comparison with published experimental data showing voltage plateau and voltage drop as plating indicators and optionally includes an explicit re-intercalation reaction that is shown to suppress macroscopic plating hints in the specific case of a cell not showing evident plating signs. This model is used to create degradation maps over a wide range of conditions and an in-depth spatiotemporal analysis of the anode behaviour at the mesoscopic and microscopic scales, demonstrating the dynamic and nonlinear interaction between the intercalation and plating reactions.
A deeper outlook on the SEI formation and growth is presented, together with the qualitative description of three different 1D-models with a decreasing level of detail, developed with the purpose of ideally being included in future in more comprehensive multiscale frameworks.
Finally, the extended model is successfully coupled with a previously developed SEI model to result in an original modelling framework able to simulate both degradation processes and their continuous positive feedback.
The manufacturing of conventional electronics has become a highly complicated process, which requires intensive investment. In this context, printed electronics keeps attracting attention from both academia and industry. The primary reason is the simplification of the manufacturing process via additive printing technology such as ink-jet printing. Consequently, advantages are realized such as on-demand fabrication, minimal material waste and versatile choice of substrate materials. Central to the development of printed electronic circuits are printed transistors. Recently, metal oxide semiconductors such as indium oxide have become promising materials for the fabrication of printed transistors due to their high charge mobility. Furthermore, electrolyte-gating also provides benefits such as the low-voltage operation in sub-1 V regime due to the large gate capacitance provided by electrical double layers. This opens new possibilities to fabricate printed devices and circuits for niche applications.
To facilitate the design and fabrication of printed circuits, the development of compact models is necessary. However, most of the current works have focused on the study of the static behavior of transistors, while the in-depth understanding of other characteristics such as the dynamic or noise behavior is missing. To this end, the purpose of this work is the comprehensive study on capacitance and noise properties of inkjet-printed electrolyte-gated thin-film transistors (EGT) based on indium oxide semiconductors. Proper modeling approaches are also proposed to capture accurately the electrical behaviour, which can be further utilized to enable advanced analysis of digital, analog and mixed-signal circuits.
In this work, the capacitance of EGTs is characterized using voltage-dependent impedance spectroscopy. Intrinsic and extrinsic effects are carefully separated by using de-embedding test structures. Also, a dedicated equivalent circuit model is established to offer accurate simulations of the measured frequency response of the gate impedance. Based on that, it is revealed that top-gated EGTs have the potential to reach operation frequency in the kHz regime with proper optimizations of materials and printing process. Furthermore, a Meyer-like model is proposed to accurately capture the capacitance-voltage characteristics of the lumped terminal capacitance. Both parasitic and nonquasi-static effects are considered. This further enables the AC and transient analysis of complex circuits in circuit simulators.
Following, the study of noise properties in the field of printed electronics is conducted. Low-frequency noise of EGTs is characterized using a reliable experimental setup. By examining measured noise spectra of the drain current at various gate voltages, the number fluctuation with correlated mobility fluctuation has been determined as the primary noise mechanism. Based on that, normalized flat-band voltage noise can be determined as the key performance metrics, which is only 1.08 × 10−7 V^2 µm^2, significantly lower in comparison with other thin-film technologies, which are based on dielectric gating and semiconductors such as IZO and IGZO. A plausible reason could be the large gate capacitance offered by the electrical double layers. This renders EGT technology useful for low-noise and sensitive applications such as sensor periphery circuits.
Last but not least, various circuit designs based on EGT technology are proposed, including basic digital circuits such as inverters and ring oscillators. Their performance metrics such as the propagation delay and power consumption are extensively characterized. Also, the first design of a printed full-wave rectifier is presented by using diode-connected EGTs, which features near-zero threshold voltage. As a consequence, the presented rectifier can effectively process input voltage with a small amplitude of 100 mV and a cut-off frequency of 300 Hz, which is particularly attractive for the application domain of energy harvesting. Additionally, the previously established capacitance models are verified on those circuits, which provide a satisfactory agreement between the simulation and measurement data.
Printed electronics, due to its manufacturability using printing technology, allows for fabrication on large areas and the usage of flexible substrates and thus enables novel applications. Non-impact printing technology, such as inkjet-printing, permits for flexible, decentralized manufacturing of electronic devices and systems. This further facilitates split-manufacturing in security-critical electrical components, as well as a maximum in design flexibility in terms of free form factors and non-standardized structures with different geometrical sizes, reaching from a few micrometers up to several millimeters.
Based on the technological benefits printed electronics offers, it provides an interesting counterpart to classical silicon-based electronics, which is usually densely integrated on miniaturized, rigid areas. By utilizing both technologies in a complementary manner, novel systems in the form of hybrid systems can be enabled. Whilst hybrid systems, incorporating passive printed components and electrically conductive wiring concepts, are already commercialized, complex printed systems, which also utilize active components remain rare. To enable more complex (hybrid) systems, various building blocks are required. This includes possibilities for lightweight, printed data storage, the capability to provide sustainable, self-powered printed components and especially circuits for secure, unique identification for holistic printed systems, deployed in the internet of things.
The presented thesis focuses on inkjet-printed electronic devices, circuits and hybrid systems. It investigates solutions for current scientific questions in the area of efficient data storage, sustainable electronics and hardware-based security in printed electronics.
For data storage, an inkjet-printed memristor is developed. The device is fully electrically evaluated with a focus on its data storage capabilities. Furthermore, the printed device is of special interest due to its easy manufacturability and integration capabilities. The experimental analysis reveals that the developed memristor is highly suitable as lightweight non-volatile memory device.
In order to enable sustainable electronic systems, an inkjet-printed full-wave rectifier based on near-zero threshold voltage electrolyte-gated transistors is developed and fully electrically characterized. The circuit is capable for small alternating voltage rectification of low-frequency vibration energy harvesters in the sub-volt region. This provides an important building block in enabling sustainable, self-powered electronic systems. The inkjet-printed full-wave rectifier is evaluated by electrical simulation and experimentally.
To tackle hardware-based security for printed electronics, two implementations for inkjet-printed physically unclonable functions are developed and presented. For unique identification, intrinsic variation in active printed devices are exploited. One implementation is based on a crossbar architecture, incorporating integrable electrolyte-gated transistor cells. The second implementation, the so-called differential circuit physically unclonable function, is based on inverter structures, which provide the basis for unique response generation. Both physically unclonable functions are evaluated using an electrical simulation-based approach and experimentally. The differential circuit approach is furthermore fully integrated within a silicon-based electronic platform environment and serves as intrinsic variation source in a hybrid system. The hybrid system physically unclonable function is fully verified regarding performance metrics and is capable to generate highly unique responses for secure identification.
Im Jahre 2010 bot die Hochschule Offenburg ein Medizintechnikstudium mit dem Schwerpunkt ’Kardiologie, Elektrophysiologie und elektronische kardiologische Implantate’ als Bachelor- und später auch Masterstudiengang an. Ziel des auf diesen Schwerpunkt ausgelegten didaktischen Lehrkonzeptes ist die Vermittlung sofort anwendungsbereiten theoretischen Wissens und praktischen Könnens, welches die Absolventinnen und Absolventen in ihrer künftigen Berufsausübung in der Industrie oder als technische Partner der behandelnden Ärztinnen und Ärzte in hochspezialisierten klinischen Einrichtungen benötigen.
Aufgrund fehlender kommerzieller Angebote ist zur Umsetzung dieses Lehrkonzeptes die ingenieurtechnische Realisierung geeigneter Lehrmittel zwingend erforderlich. Dies betrifft die hard- und softwareseitige Erstellung visueller Demonstrationsmöglichkeiten für pathologische und implantatinduzierte Herzrhythmen, sowie die synthetische Bereitstellung originalgetreuer elektrokardiographischer Ableitsignale aus der klinischen Routine. Des Weiteren den Aufbau von in-vitro Trainingssystemen zu Therapien mit elektronischen kardiologischen Implantaten sowie zur Hochfrequenz-Katheterablation.
Insbesondere die Wahlfächer ’Programmierung von Herzschrittmachern’ und ‚Programmierung von Defibrillatoren’, deren Besuch den Teilnehmenden einen besonders raschen Berufseinstieg ermöglichen sollte, wurden in didaktischer Hinsicht in engem Bezug zum 4-Komponenten-Instruktionsdesign-Modell der Lehre gestaltet.
Durch den kontinuierlichen Einsatz der Instrumente der formativen Evaluation gelangen sowohl deutliche Verbesserungen am Gesamtkonzept der Lehrveranstaltungen als auch an den dort eingesetzten, selbst realisierten Lösungen des benannten speziellen Lehr- und Trainingsequipments.
Eine summative Evaluation des Lehrkonzeptes ist aufgrund seines Alleinstellungsmerkmals schwierig. Aus diesem Grund erschien die quantitative Prüfung des Einflusses eines Besuchs des praktisch orientierten Wahlfachs ’Programmierung von Herzschrittmachern’ auf die Note der kombinierten Abschlussklausur in den Fächern ’Elektrokardiographie’ und ’Elektrostimulation’ sinnvoll. In diese Evaluation eingeschlossen wurde eine Kohorte von 221 Studierenden, 76 Frauen und 145 Männer, von denen 93 am Wahlfach nicht teilnahmen und 128 die es besucht hatten.
Über 7 zusammengefasste Studienjahre zeigte sich, dass die praktische Ausbildung im Wahlfach ’Programmierung von Herzschrittmachern’ das Leistungsniveau der Studierenden der Medizintechnik in der kombinierten Abschlussprüfung ’Elektrokardiographie und Elektrostimulation’ deutlich beeinflusste.
Das im Rahmen dieser Arbeit mitgestaltete Lehrkonzept, die realisierten Lehrmaterialien und Lehrumgebungen wurden im Bachelor- und Masterstudiengang der Medizintechnik an der Hochschule Offenburg in den Praktika, Seminaren und Vorlesungen des Schwerpunktes ’Kardiologie, Elektrophysiologie und elektronische kardiologische Implantate’ vielfältig genutzt. Sie ermöglichten die Gestaltung interaktiver praktischer Weiterbildungsveranstaltungen für ärztliches und mittleres medizinisches Personal und für auf diesen Gebieten tätige medizintechnische Firmen.