- About
-
The Global ETD Search service is a free service for researchers
to find electronic theses and dissertations. This service is
provided by the
Networked Digital Library of Theses and Dissertations.
Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
Search results
Showing 41 to 50 of 54 (0.01 seconds)| 41 |
Stretchable MagnetoelectronicsMelzer, Michael 19 November 2015 (has links)
In this work, stretchable magnetic sensorics is successfully established by combining metallic thin films revealing a giant magnetoresistance effect with elastomeric materials. Stretchability of the magnetic nanomembranes is achieved by specific morphologic features (e.g. wrinkles), which accommodate the applied tensile deformation while maintaining the electrical and magnetic integrity of the sensor device. The entire development, from the demonstration of the world-wide first elastically stretchable magnetic sensor to the realization of a technology platform for robust, ready-to-use elastic magnetoelectronics with fully strain invariant properties, is described. The prepared soft giant magnetoresistive devices exhibit the same sensing performance as on conventional rigid supports, but can be stretched uniaxially or biaxially reaching strains of up to 270% and endure over 1,000 stretching cycles without fatigue. The comprehensive magnetoelectrical characterization upon tensile deformation is correlated with in-depth structural investigations of the sensor morphology transitions during stretching.
With their unique mechanical properties, the elastic magnetoresistive sensor elements readily conform to ubiquitous objects of arbitrary shapes including the human skin. This feature leads electronic skin systems beyond imitating the characteristics of its natural archetype and extends their cognition to static and dynamic magnetic fields that by no means can be perceived by human beings naturally. Various application fields of stretchable magnetoelectronics are proposed and realized throughout this work. The developed sensor platform can equip soft electronic systems with navigation, orientation, motion tracking and touchless control capabilities. A variety of novel technologies, like smart textiles, soft robotics and actuators, active medical implants and soft consumer electronics will benefit from these new magnetic functionalities.:Outline
List of abbreviations 7
1. INTRODUCTION
1.1 Motivation and scope of this work 8
1.1.1 A brief review on stretchable electronics 8
1.1.2 Stretchable magnetic sensorics 10
1.2 Technological approach 11
1.3 State-of-the-art 12
2. THEORETICAL BACKGROUND
2.1 Magnetic coupling phenomena in layered structures 14
2.1.1 Magnetic interlayer exchange coupling 14
2.1.2 Exchange bias 15
2.1.3 Orange peel coupling 16
2.2 Giant magnetoresistance 17
2.2.1 Electronic transport through ferromagnets 17
2.2.2 The GMR effect 19
2.2.3 GMR multilayers 20
2.2.4 Spin valves 21
2.3 Theory of elasticity 22
2.3.1 Elastomeric materials 22
2.3.2 Stress and strain 23
2.3.3 Rubber elasticity 25
2.3.4 The Poisson effect 26
2.3.5 Viscoelasticity 27
2.3.6 Bending strain in a stiff film on a flexible support 27
2.4 Approaches to stretchable electronic systems 28
2.4.1 Microcrack formation 28
2.4.2 Meanders and compliant patterns 29
2.4.3 Surface wrinkling 30
2.4.4 Rigid islands 32
3. METHODS & MATERIALS
3.1 Sample fabrication 34
3.1.1 Polydimethylsiloxane (PDMS) 34
3.1.2 PDMS film preparation 35
3.1.3 Lithographic structuring on the PDMS surface. 36
3.1.4 Magnetic thin film deposition 38
3.1.5 GMR layer stacks 40
3.1.6 Mechanically induced pre-strain 43
3.1.7 Methods and materials for the direct transfer of GMR sensors 45
3.1.8 Materials used for imperceptible GMR sensors 47
3.2 Characterization 48
3.2.1 GMR characterization setup with in situ stretching capability 48
3.2.2 Sample mounting 50
3.2.3 Electrical contacting of stretchable sensor devices 51
3.2.4 Customized demonstrator electronics 52
3.2.5 Microscopic investigation techniques 53
4. RESULTS & DISCUSSION
4.1 GMR multilayer structures on PDMS 54
4.1.1 Pre-characterization 54
4.1.2 Thermally induced wrinkling 55
4.1.3 Self-healing effect 57
4.1.4 Demonstrator: Magnetic detection on a curved surface 60
4.1.5 Sensitivity enhancement 61
4.1.6 GMR sensors in circumferential geometry 64
4.1.7 Stretchability test 67
4.2 Stretchable spin valves 69
4.2.1 Random wrinkles and periodic fracture 70
4.2.2 GMR characterization 73
4.2.3 Stretching of spin valves 74
4.2.4 Microcrack formation mechanism 76
4.3 Direct transfer printing of GMR sensorics 81
4.3.1 The direct transfer printing process 82
4.3.2 Direct transfer of GMR microsensor arrays 84
4.3.3 Direct transfer of compliant meander shaped GMR sensors 86
4.4 Imperceptible magnetoelectronics 89
4.4.1 GMR multilayers on ultra-thin PET membranes 89
4.4.2 Imperceptible GMR sensor skin 92
4.4.3 Demonstrator: Fingertip magnetic proximity sensor 93
4.4.4 Ultra-stretchable GMR sensors 94
4.4.5 Biaxial stretchability 99
4.4.6 Demonstrator: Dynamic detection of diaphragm inflation 101
5. CONCLUSIONS & OUTLOOK
5.1 Achievements 102
5.2 Outlook 104
5.2.1 Further development steps 104
5.2.2 Prospective applications. 105
5.3 Technological impact: flexible Bi Hall sensorics 106
5.3.1 Application potential 106
5.3.2 Thin and flexible Hall probes 107
5.3.3 Continuative works and improvements 108
5.4 Activities on technology transfer and public relations 108
Appendix
References 110
Selbständigkeitserklärung 119
Acknowledgements 120
Curriculum Vitae 121
Scientific publications, contributions, patents, grants & prizes 122
|
| 42 |
Active Lightweight – End effector (ALE) for the collaborative RoboticsChen, Liang 09 December 2022 (has links)
This thesis provides a systematic guideline for evaluating, integrating and designing the collaborative end effector system associated with commercially available collaborative robots (cobots). On the basis of ISO/TS 15066:2016, customers’ demands are categorised as a macro demand framework and micro demand variables, which are parameterised and hierarchised. By analysing these parameters, the collaborative degree is determined to correlate the hazards with protection measures, which can demonstrate the collaborative safety level transparently. After that, the safety protection measures are specifically proposed corresponding to the potential risks. Finally, an industrial application is evaluated, a novel adapter utilised on the UR5 cobot is illustrated, and its characteristics for the collaborative operation are described.:1 Introduction
2 Robotic end effector in Assembly and Handling
3 Concept and Definition of Collaboration
4 Statement of the academic purpose and methodology
5 Guideline and Methodology for designing the Active Lightweight End-effector (ALE) for collaborative robots
6 Performance demand d4): multiplicity and versatility of end effector
7 A safety monitoring end effector (Adapter) for collaborative operations
8 A practical study of collaborative integration based on collaborative degree
9 Conclusion
Appendix / Diese Arbeit liefert einen systematischen Leitfaden für die Bewertung, Integration und Gestaltung des kollaborierenden Endeffektorsystems in Verbindung mit kommerziell verfügbaren kollaborativen Robotern (Kobots). Auf der Grundlage der ISO/TS 15066:2016 werden die Anforderungen der Kunden in einen Makro-Bedarfsrahmen und Mikro-Bedarfsvariablen kategorisiert, die parametrisiert und hierarchisiert werden. Durch die Analyse dieser Parameter wird der Kollaborationsgrad ermittelt, um die Gefährdungen mit Schutzmaßnahmen zu korrelieren, die die kollaborierende Sicherheitsstufe transparent darstellen können. Danach werden die Schutzmaßnahmen entsprechend den potenziellen Risiken vorgeschlagen. Schließlich wird ein industrieller Anwendungsfall bewertet, ein neuartiger Adapter für den Einsatz an einem Roboter UR5 erläutert und dessen Kenndaten für den kollaborierenden Betrieb beschrieben.:1 Introduction
2 Robotic end effector in Assembly and Handling
3 Concept and Definition of Collaboration
4 Statement of the academic purpose and methodology
5 Guideline and Methodology for designing the Active Lightweight End-effector (ALE) for collaborative robots
6 Performance demand d4): multiplicity and versatility of end effector
7 A safety monitoring end effector (Adapter) for collaborative operations
8 A practical study of collaborative integration based on collaborative degree
9 Conclusion
Appendix
|
| 43 |
Contributions to the Simulation and Optimization of the Manufacturing Process and the Mechanical Properties of Short Fiber-Reinforced Plastic PartsOspald, Felix 16 December 2019 (has links)
This thesis addresses issues related to the simulation and optimization of the injection molding of short fiber-reinforced plastics (SFRPs).
The injection molding process is modeled by a two phase flow problem.
The simulation of the two phase flow is accompanied by the solution of the Folgar-Tucker equation (FTE) for the simulation of the moments of fiber orientation densities.
The FTE requires the solution of the so called 'closure problem'', i.e. the representation of the 4th order moments in terms of the 2nd order moments.
In the absence of fiber-fiber interactions and isotropic initial fiber density, the FTE admits an analytical solution in terms of elliptic integrals.
From these elliptic integrals, the closure problem can be solved by a simple numerical inversion.
Part of this work derives approximate inverses and analytical inverses for special cases of fiber orientation densities.
Furthermore a method is presented to generate rational functions for the computation of arbitrary moments in terms of the 2nd order closure parameters.
Another part of this work treats the determination of effective material properties for SFRPs by the use of FFT-based homogenization methods.
For these methods a novel discretization scheme, the 'staggered grid'' method, was developed and successfully tested. Furthermore the so called 'composite voxel'' approach was extended to nonlinear elasticity, which improves the approximation of material properties at the interfaces and allows the reduction of the model order by several magnitudes compared to classical approaches. Related the homogenization we investigate optimal experimental designs to robustly determine effective elastic properties of SFRPs with the least number of computer simulations.
Finally we deal with the topology optimization of injection molded parts, by extending classical SIMP-based topology optimization with an approximate model for the fiber orientations.
Along with the compliance minimization by topology optimization we also present a simple shape optimization method for compensation of part warpage for an black-box production process.:Acknowledgments v
Abstract vii
Chapter 1. Introduction 1
1.1 Motivation 1
1.2 Nomenclature 3
Chapter 2. Numerical simulation of SFRP injection molding 5
2.1 Introduction 5
2.2 Injection molding technology 5
2.3 Process simulation 6
2.4 Governing equations 8
2.5 Numerical implementation 18
2.6 Numerical examples 25
2.7 Conclusions and outlook 27
Chapter 3. Numerical and analytical methods for the exact closure of the Folgar-Tucker equation 35
3.1 Introduction 35
3.2 The ACG as solution of Jeffery's equation 35
3.3 The exact closure 36
3.4 Carlson-type elliptic integrals 37
3.5 Inversion of R_D-system 40
3.6 Moment tensors of the angular central Gaussian distribution on the n-sphere 49
3.7 Experimental evidence for ACG distribution hypothesis 54
3.8 Conclusions and outlook 60
Chapter 4. Homogenization of SFRP materials 63
4.1 Introduction 63
4.2 Microscopic and macroscopic model of SFRP materials 63
4.3 Effective linear elastic properties 65
4.4 The staggered grid method 68
4.5 Model order reduction by composite voxels 80
4.6 Optimal experimental design for parameter identification 93
Chapter 5. Optimization of parts produced by SFRP injection molding 103
5.1 Topology optimization 103
5.2 Warpage compensation 110
Chapter 6. Conclusions and perspectives 115
Appendix A. Appendix 117
A.1 Evaluation of R_D in Python 117
A.2 Approximate inverse for R_D in Python 117
A.3 Inversion of R_D using Newton's/Halley's method in Python 117
A.4 Inversion of R_D using fixed point method in Python 119
A.5 Moment computation using SymPy 120
A.6 Fiber collision test 122
A.7 OED calculation of the weighting matrix 123
A.8 OED Jacobian of objective and constraints 123
Appendix B. Theses 125
Bibliography 127 / Diese Arbeit befasst sich mit Fragen der Simulation und Optimierung des Spritzgießens von kurzfaserverstärkten Kunststoffen (SFRPs).
Der Spritzgussprozess wird durch ein Zweiphasen-Fließproblem modelliert.
Die Simulation des Zweiphasenflusses wird von der Lösung der Folgar-Tucker-Gleichung (FTE) zur Simulation der Momente der Faserorientierungsdichten begleitet.
Die FTE erfordert die Lösung des sogenannten 'Abschlussproblems'', d. h. die Darstellung der Momente 4. Ordnung in Form der Momente 2. Ordnung.
In Abwesenheit von Faser-Faser-Wechselwirkungen und anfänglich isotroper Faserdichte lässt die FTE eine analytische Lösung durch elliptische Integrale zu.
Aus diesen elliptischen Integralen kann das Abschlussproblem durch eine einfache numerische Inversion gelöst werden.
Ein Teil dieser Arbeit leitet approximative Inverse und analytische Inverse für spezielle Fälle von Faserorientierungsdichten her.
Weiterhin wird eine Methode vorgestellt, um rationale Funktionen für die Berechnung beliebiger Momente in Bezug auf die Abschlussparameter 2. Ordnung zu generieren.
Ein weiterer Teil dieser Arbeit befasst sich mit der Bestimmung effektiver Materialeigenschaften für SFRPs durch FFT-basierte Homogenisierungsmethoden.
Für diese Methoden wurde ein neuartiges Diskretisierungsschema 'staggerd grid'' entwickelt und erfolgreich getestet. Darüber hinaus wurde der sogenannte 'composite voxel''-Ansatz auf die nichtlineare Elastizität ausgedehnt, was die Approximation der Materialeigenschaften an den Grenzflächen verbessert und die Reduzierung der Modellordnung um mehrere Größenordnungen im Vergleich zu klassischen Ansätzen ermöglicht. Im Zusammenhang mit der Homogenisierung untersuchen wir optimale experimentelle Designs, um die effektiven elastischen Eigenschaften von SFRPs mit der geringsten Anzahl von Computersimulationen zuverlässig zu bestimmen.
Schließlich beschäftigen wir uns mit der Topologieoptimierung von Spritzgussteilen, indem wir die klassische SIMP-basierte Topologieoptimierung um ein Näherungsmodell für die Faserorientierungen erweitern.
Neben der Compliance-Minimierung durch Topologieoptimierung stellen wir eine einfache Formoptimierungsmethode zur Kompensation von Teileverzug für einen Black-Box-Produktionsprozess vor.:Acknowledgments v
Abstract vii
Chapter 1. Introduction 1
1.1 Motivation 1
1.2 Nomenclature 3
Chapter 2. Numerical simulation of SFRP injection molding 5
2.1 Introduction 5
2.2 Injection molding technology 5
2.3 Process simulation 6
2.4 Governing equations 8
2.5 Numerical implementation 18
2.6 Numerical examples 25
2.7 Conclusions and outlook 27
Chapter 3. Numerical and analytical methods for the exact closure of the Folgar-Tucker equation 35
3.1 Introduction 35
3.2 The ACG as solution of Jeffery's equation 35
3.3 The exact closure 36
3.4 Carlson-type elliptic integrals 37
3.5 Inversion of R_D-system 40
3.6 Moment tensors of the angular central Gaussian distribution on the n-sphere 49
3.7 Experimental evidence for ACG distribution hypothesis 54
3.8 Conclusions and outlook 60
Chapter 4. Homogenization of SFRP materials 63
4.1 Introduction 63
4.2 Microscopic and macroscopic model of SFRP materials 63
4.3 Effective linear elastic properties 65
4.4 The staggered grid method 68
4.5 Model order reduction by composite voxels 80
4.6 Optimal experimental design for parameter identification 93
Chapter 5. Optimization of parts produced by SFRP injection molding 103
5.1 Topology optimization 103
5.2 Warpage compensation 110
Chapter 6. Conclusions and perspectives 115
Appendix A. Appendix 117
A.1 Evaluation of R_D in Python 117
A.2 Approximate inverse for R_D in Python 117
A.3 Inversion of R_D using Newton's/Halley's method in Python 117
A.4 Inversion of R_D using fixed point method in Python 119
A.5 Moment computation using SymPy 120
A.6 Fiber collision test 122
A.7 OED calculation of the weighting matrix 123
A.8 OED Jacobian of objective and constraints 123
Appendix B. Theses 125
Bibliography 127
|
| 44 |
Ferromagnet-Free Magnetoelectric Thin Film ElementsKosub, Tobias 25 November 2016 (has links)
The work presented in this thesis encompasses the design, development, realization and testing of novel magnetoelectric thin film elements that do not rely on ferromagnets, but are based entirely on magnetoelectric antiferromagnets such as Cr2O3. Thin film spintronic elements, and in particular magnetoelectric transducers, are crucial building blocks of high efficiency data processing schemes that could complement conventional electronic data processing in the future. Recent developments in magnetoelectrics have revealed, that exchange biased systems are ill-suited to electric field induced switching of magnetization due to the strong coupling of their ferromagnetic layer to magnetic fields. Therefore, ferromagnet-free magnetoelectric elements are proposed here in an effort to mitigate the practical problems associated with existing exchange biased magnetoelectric elements.
This goal is achieved by establishing an all-electric read-out method for the antiferromagnetic order parameter of thin films, which allows to omit the ferromagnet from conventional exchange biased magnetoelectric elements. The resulting ferromagnet-free magnetoelectric elements show greatly reduced writing thresholds, enabled operation at room temperature and do not require a pulsed magnetic field, all of which is in contrast to state-of-the-art exchange biased magnetoelectric systems.
The novel all-electric read-out method of the magnetic field-invariant magnetization of antiferromagnets, so-called spinning-current anomalous Hall magnetometry, can be widely employed in other areas of thin film magnetism. Its high precision and its sensitivity to previously invisible phenomena make it a promising tool for various aspects of thin solid films. Based on this technique, a deep understanding could be generated as to what physical mechanisms drive the antiferromagnetic ordering in thin films of magnetoelectric antiferromagnets. As spinning-current anomalous Hall magnetometry is an integral probe of the magnetic properties in thin films, it offers no intrinsic scale sensitivity. In order to harness its great precision for scale related information, a statistical framework was developed, which links macroscopic measurements with microscopic properties such as the antiferromagnetic domain size.:TABLE OF CONTENTS
Abbreviations 9
1 Introduction 11
1.1 Motivation 11
1.2 Objectives 12
1.3 Organization of the thesis 13
2 Background 15
2.1 History of magnetoelectric coupling 15
2.2 Long range magnetic ordering 16
2.2.1 Magnetic order parameter and field susceptibility 17
2.2.2 Magnetic proximity effect 19
2.2.3 Exchange bias 20
2.3 Phenomenology of magnetoelectric coupling 21
2.3.1 The linear magnetoelectric effect 21
2.3.2 Magnetoelectric pressure on the antiferromagnetic order parameter 22
2.3.3 Switching the antiferromagnetic order parameter 23
2.4 Realized magnetoelectric thin film elements 24
2.4.1 BiFeO3/CoFe system 24
2.4.2 Cr2O3/Co/Pt system 25
3 Experimental methods 27
3.1 Development of ferromagnet free magnetoelectric elements 28
3.1.1 The substrate 29
3.1.2 The Cr2O3 bulk and top surface 31
3.1.3 The V2O3 or Pt bottom electrodes 33
3.1.4 Epitaxial relationships 34
3.1.5 The Cr2O3 bottom interface 39
3.1.6 Twinning of Cr2O3 39
3.1.7 Hall crosses and patterning processes 43
3.2 Magnetotransport measurements 44
3.2.1 Hall effects 45
3.2.2 Anomalous Hall effect 46
3.2.3 Magnetoelectric writing 47
3.2.4 All electric read out 49
3.3 The experimental setup 50
3.3.1 Temperature control 50
3.3.2 Magnetic field control 51
4 Spinning-current anomalous Hall magnetometry 53
4.1 Characteristics of the technique 53
4.1.1 Operational principle 53
4.1.2 Advantages 55
4.1.3 Magnetic hysteresis loops and field-invariant magnetization 55
4.1.4 Measurement of field-invariant magnetization 56
4.1.5 Limitations 58
4.2 Application of SCAHM to Cr2O3(0001) thin films 59
4.2.1 Criticality and distribution of the antiferromagnetic phase transition 61
4.2.2 Evaluation of the magnetic proximity effect 64
4.3 SCAHM with thin metallic antiferromagnetic IrMn films 65
4.3.1 [Pt/Co]4/IrMn exchange bias system 65
4.3.2 Isolated antiferromagnetic IrMn thin films 67
5 Magnetoelectric performance 69
5.1 Magnetoelectric field cooling 69
5.2 The gate bias voltage 71
5.3 Isothermal binary magnetoelectric writing in Cr2O3 72
6 Order parameter selection in magnetoelectric antiferromagnets 77
6.1 Uncompensated magnetic moment 77
6.2 Extrinsic causes for broken sublattice equivalence 81
6.3 The V2O3 gate electrode 83
7 Measurement of microscopic properties with an integral probe 87
7.1 Interentity magnetic exchange coupling 87
7.2 Ensemble formalism for the entity size determination 90
7.3 Estimation of the entity sizes 94
7.4 Microscopic confirmation of the ensemble model 97
8 Summary and Outlook 101
8.1 Goal-related achievements 101
8.1.1 All-electric read-out of the AF order parameter 101
8.1.2 Electric field induced writing of the AF order parameter 102
8.2 Further achievements 103
8.2.1 Foreseen impact of SCAHM on thin film magnetism 103
8.2.2 Practical optimization routes of magnetoelectric Cr2O3 systems 104
8.2.3 Theoretical work 105
8.3 Future directions 105
8.3.1 Development of Cr2O3-based magnetoelectric systems 105
8.3.2 Applications of SCAHM 106
References 107
Erklärung 113
Acknowledgements 115
Curriculum Vitae 117
Scientific publications, contributions, patents 119
|
| 45 |
Modulbasierte Synthese ebener Koppelgetriebe unter Einbeziehung kinetischer KenngrößenHeinrich, Stefan 07 November 2018 (has links)
Die Entwicklung mechanischer Antriebskonzepte für nichtlineare Bewegungsaufgaben stellt bis heute ein komplexes und domänenübergreifendes Fachgebiet des Maschinenbaus dar. Auf dem Gebiet der ebenen Koppelgetriebe gibt es dabei seit vielen Jahren Versuche, die optimale Lösung für eine Aufgabe unter Berücksichtigung kinetischer Kenngrößen zu finden. Die vorliegende Arbeit stellt eine Methodik vor, die sowohl den klassischen Verfahren der Getriebetechnik als auch den Ansätzen der Mechanik zum Ausgleich der Massenwirkungen im Getriebe gerecht wird. Der entwickelte Ansatz des modulbasierten Analyse-Synthese-Parameter-Abgleiches (ASPA) erlaubt erstmals eine domänenübergreifende Simulation komplexer Antriebskonzepte auf Basis einer neuartigen modularen Synthesebibliothek. Diese lässt sich dank umfangreicher Dokumentation und der dargestellten Programmablaufpläne in beliebige Software implementieren. Die exemplarisch im Systemsimulator SimulationX implementierte Bibliothek ermöglicht somit unter anderem die Anwendung der klassischen Drei- und Vierlagensynthese im bewegten oder ruhenden Bezugssystem für Dreh- und Schubgelenkketten. Neben der Ausgabe gerundeter Getriebeabmessungen eröffnet der beschriebene Ansatz somit die Berücksichtigung kinetischer Kenngrößen wie den Pendelschwingungen in spielbehafteten Gelenken oder der Änderung der Trägheitskenngrößen während der Synthese. Weiterführend kann eine multikriterielle Optimierung der noch freien Syntheseparameter erfolgen. / Developing nonlinear transmitting planar coupler linkages represents a domain spanning area in mechanical engineering. In recent years many efforts have been made to determine the optimal planar linkage regarding kinetic characteristics. This thesis introduces a method linking classical synthesis procedures with mechanical approaches for a dynamically balanced mechanism. For the first time, the module based analysis-synthesis-parameter-adjustment (ASPA) allows for a domain spanning simulation of complex drive assemblies based on a novel modular synthesis library. Due to an extensive documentation and detailed program flow charts it is possible to implement the library in arbitrary software environments. The exemplarily implemented library in SimulationX allows to apply the classical three- and four-position synthesis within a steady or moving reference frame of revolute or prismatic joint chains. Further, the modules return rounded link dimensions. By applying this library according to ASPA it is now possible to account for kinetic boundaries such as pendulum oscillations of joints with joint clearance or the change of mass properties during the position synthesis. Thus, a multi-criteria optimization of the remaining free synthesis parameters can be applied.
|
| 46 |
Multifunctional Droplet-based Micro-magnetofluidic DevicesLin, Gungun 23 August 2016 (has links) (PDF)
Confronted with the global demographic changes and the increasing pressure on modern healthcare system, there has been a surge of developing new technology platforms in the past decades. Droplet microfluidics is a prominent example of such technology platforms, which offers an efficient format for massively parallelized screening of a large number of samples and holds great promise to boost the throughput and reduce the costs of modern biomedical activities. Despite recent achievements, the realization of a compact and generic screening system which is suited for resource-limited settings and point-of-care applications remains elusive.
To address the above challenges, the dissertation focuses on the development of a compact multifunctional droplet micro-magnetofluidic system by exploring the advantages of magnetic in-flow detection principles. The methodologies behind a novel technique for biomedical applications, namely, magnetic in-flow cytometry have been put forth, which encompass magnetic indexing schemes, quantitative multiparametric analytics and magnetically-activated sorting. A magnetic indexing scheme is introduced and intrinsic to the magnetofluidic system. Two parameters characteristic of the magnetic signal when detecting magnetically functionalized objects, i.e. signal amplitude and peak width, providing information which is necessary to perform quantitative analysis in the spirit of optical cytometry has been proposed and realized. Magnetically-activated sorting is demonstrated to actively select individual droplets or to purify a population of droplets of interest. Together with the magnetic indexing scheme and multiparametric analytic technique, this functionality synergistically enables controlled synthesis, quality administration and screening of encoded magnetic microcarriers, which is crucial for the practical realization of magnetic suspension arrays technologies. Furthermore, to satisfy the needs of cost-efficient fabrication and high-volume delivery, an approach to fabricate magnetofluidic devices on flexible foils is demonstrated. The resultant device retains high performance of its rigid counterpart and exhibits excellent mechanical properties, which promises long-term stability in practical applications.
|
| 47 |
Ferromagnet-Free Magnetoelectric Thin Film ElementsKosub, Tobias 12 December 2016 (has links) (PDF)
The work presented in this thesis encompasses the design, development, realization and testing of novel magnetoelectric thin film elements that do not rely on ferromagnets, but are based entirely on magnetoelectric antiferromagnets such as Cr2O3. Thin film spintronic elements, and in particular magnetoelectric transducers, are crucial building blocks of high efficiency data processing schemes that could complement conventional electronic data processing in the future. Recent developments in magnetoelectrics have revealed, that exchange biased systems are ill-suited to electric field induced switching of magnetization due to the strong coupling of their ferromagnetic layer to magnetic fields. Therefore, ferromagnet-free magnetoelectric elements are proposed here in an effort to mitigate the practical problems associated with existing exchange biased magnetoelectric elements.
This goal is achieved by establishing an all-electric read-out method for the antiferromagnetic order parameter of thin films, which allows to omit the ferromagnet from conventional exchange biased magnetoelectric elements. The resulting ferromagnet-free magnetoelectric elements show greatly reduced writing thresholds, enabled operation at room temperature and do not require a pulsed magnetic field, all of which is in contrast to state-of-the-art exchange biased magnetoelectric systems.
The novel all-electric read-out method of the magnetic field-invariant magnetization of antiferromagnets, so-called spinning-current anomalous Hall magnetometry, can be widely employed in other areas of thin film magnetism. Its high precision and its sensitivity to previously invisible phenomena make it a promising tool for various aspects of thin solid films. Based on this technique, a deep understanding could be generated as to what physical mechanisms drive the antiferromagnetic ordering in thin films of magnetoelectric antiferromagnets. As spinning-current anomalous Hall magnetometry is an integral probe of the magnetic properties in thin films, it offers no intrinsic scale sensitivity. In order to harness its great precision for scale related information, a statistical framework was developed, which links macroscopic measurements with microscopic properties such as the antiferromagnetic domain size.
|
| 48 |
The Hair Bundle: Fluid-Structure Interaction in the Inner EarBaumgart, Johannes 22 December 2010 (has links) (PDF)
A multitude of processes cooperate to produce the sensation of sound. The key initial step, the transformation from mechanical motion into an electrical signal, takes place in highly specialized mechanosensitive organelles that are called hair bundles due to their characteristic appearance. Each hair bundle comprises many apposed cylindrical stereocilia that are located in a liquid-filled compartment of the inner ear. The viscous liquid surrounding the hair bundle dissipates energy and dampens oscillations, which poses a fundamental physical challenge to the high sensitivity and sharp frequency selectivity of hearing. To understand the structure-function relationship in this complex system, a realistic physical model of the hair bundle with an appropriate representation of the fluid-structure interactions is needed to identify the relevant physical effects.
In this work a novel approach is introduced to analyze the mechanics of the fluid-structure interaction problem in the inner ear. Because the motions during normal mechanotransduction are much smaller than the geometrical scales, a unified linear system of equations describes with sufficient accuracy the behavior of the liquid and solid in terms of a displacement variable. The finite-element method is employed to solve this system of partial differential equations. Based on data from the hair bundle of the bullfrog's sacculus, a detailed model is constructed that resolves simultaneously the interaction with the surrounding liquid as well as the coupling liquid in the narrow gaps between the individual stereocilia. The experimental data are from high-resolution interferometric measurements at physiologically relevant amplitudes in the range from a fraction of a nanometer to several tens of nanometers and over a broad range of frequencies from one millihertz to hundred kilohertz.
Different modes of motion are analyzed and their induced viscous drag is calculated. The investigation reveals that grouping stereocilia in a bundle dramatically reduces the total drag as compared to the sum of the drags on individual stereocilia moving in isolation. The stereocilia in a hair bundle are interconnected by oblique tip links that transmit the energy in a sound to the mechanotransduction channels and by horizontal top connectors that provide elastic coupling between adjacent stereocilia. During hair-bundle deflections, the tip links induce additional drag by causing small but very dissipative relative motions between stereocilia; this effect is offset by the horizontal top connectors that restrain such relative movements, assuring that the hair bundle moves as a unit and keeping the total drag low. In the model the stiffness of the links, the stiffness of the stereocilia, and the geometry are carefully adjusted to match experimental observations. The references are stiffness and drag measurements, as well as the coherence measurements for the bundle's opposite edges, both with and without the tip links. The results are further validated by a comparison with the relative motions measured in a sinusoidally stimulated bundle for the distortion frequencies at which movements are induced by the nonlinearity imposed by channel gating.
The model of the fluid-structure interactions described here provides insight into the key step in the perception of sound and the method presented provides an efficient and reliable approach to fluid-structure interaction problems at small amplitudes. / Bei der Hörwahrnehmung eines Klangs spielen viele komplexe Prozesse zusammen. Der Schlüsselprozess, die Umwandlung mechanischer Schwingungsbewegung in elektrische Signale, findet in den Haarbündeln im Innenohr statt. Diese Haarbündel sind hoch entwickelte mechanosensitive Organellen, bestehend aus vielen nahe beieinander stehenden Stereozilien umgeben von Flüssigkeit. Die beträchtliche Viskosität dieser Flüssigkeit führt zur Energiedissipation und zur Schwingungsdämpfung, was im Gegensatz zur bekannten hohen Empfindlichkeit und der ausgezeichneten Frequenzselektivität der Hörwahrnehmung steht. Um die Komponenten des Haarbündelsystems in ihrem funktionalen Zusammenspiel besser zu verstehen, bedarf es eines wirklichkeitsgetreuen Modells unter Einbeziehung der Wechselwirkung zwischen Flüssigkeit und Struktur.
Mit dieser Arbeit wird ein neuer Ansatz vorgestellt, um die Mechanik der Fluid-Struktur-Wechselwirkung im Innenohr zu analysieren. Da die Bewegungen bei der normalen Mechanotransduktion wesentlich kleiner als die geometrischen Abmessungen sind, ist es möglich, das Verhalten von Fluid und Struktur in Form der Verschiebungsvariable in einem linearen einheitlichen System von Gleichungen ausreichend genau zu beschreiben. Dieses System von partiellen Differentialgleichungen wird mit der Finite-Elemente-Methode gelöst. Basierend auf experimentell ermittelten Daten vom Haarbündel des Ochsenfrosches wird ein detailliertes Modell erstellt, welches sowohl die Interaktion mit der umgebenden Flüssigkeit als auch die koppelnde Flüssigkeit in den engen Spalten zwischen den einzelnen Stereozilien erfasst. Die experimentellen Daten sind Ergebnisse von hochauflösenden interferometrischen Messungen bei physiologisch relevanten Bewegungsamplituden im Bereich von unter einem Nanometer bis zu mehreren Dutzend Nanometern, sowie über einen breiten Frequenzbereich von einem Millihertz bis hundert Kilohertz.
Das Modell erlaubt die Berechnung der auftretenden viskosen Widerstände aus der numerischen Analyse der verschiedenen beobachteten Bewegungsmoden. Es kann gezeigt werden, dass durch die Gruppierung zu einem Bündel der Gesamtwiderstand drastisch reduziert ist, im Vergleich zur Summe der Widerstände einzelner Stereozilien, die sich individuell und unabhängig voneinander bewegen. Die einzelnen Stereozilien in einem Haarbündel sind durch elastische Strukturen mechanisch miteinander verbunden: Die Energie des Schalls wird durch schräg angeordnete sogenannte Tiplinks auf die mechanotransduktiven Kanäle übertragen, wohingegen horizontale Querverbindungen die Stereozilien direkt koppeln. Während der Haarbündelauslenkung verursachen die Tiplinks zusätzlichen Widerstand durch stark dissipative Relativbewegungen zwischen den Stereozilien. Die horizontalen Querverbindungen unterdrücken diese Bewegungen und sind dafür verantwortlich, dass sich das Haarbündel als Einheit bewegt und der Gesamtwiderstand gering bleibt. Die Steifigkeit der Stereozilien und der Verbindungselemente sowie deren Geometrie sind in dem Modell sorgfältig angepasst, um eine Übereinstimmung mit den Beobachtungen aus verschiedenen Experimenten zu erzielen. Als Referenz dienen Steifigkeits- und Widerstandsmessungen, sowie Kohärenzmessungen für die gegenüberliegenden Außenkanten des Bündels, die jeweils mit und ohne Tiplinks durchgeführt wurden. Darüberhinaus sind die Ergebnisse durch den Vergleich mit experimentell beobachteten Relativbewegungen validiert, die das Haarbündel infolge von sinusförmiger Anregung bei Distorsionsfrequenzen zeigt. Diese haben ihren Ursprung in dem nichtlinearen Prozess des öffnens von Ionenkanälen.
Das entwickelte Modell eines Haarbündels liefert neue Einblicke in den Schlüsselprozess der auditiven Wahrnehmung. Zur Behandlung von Problemen der Fluid-Struktur-Wechselwirkungen bei kleinen Amplituden hat sich der hier ausgearbeitete Ansatz als effizient und zuverlässig erwiesen.
|
| 49 |
Transition Matrix Monte Carlo Methods for Density of States PredictionHaber, René 03 July 2014 (has links) (PDF)
Ziel dieser Arbeit ist zunächst die Entwicklung einer Vergleichsgrundlage, auf Basis derer Algorithmen zur Berechnung der Zustandsdichte verglichen werden können. Darauf aufbauend wird ein bestehendes übergangsmatrixbasiertes Verfahren für das großkanonisch Ensemble um ein neues Auswerteverfahren erweitert. Dazu werden numerische Untersuchungen verschiedener Monte-Carlo-Algorithmen zur Berechnung der Zustandsdichte durchgeführt. Das Hauptaugenmerk liegt dabei auf Verfahren, die auf Übergangsmatrizen basieren, sowie auf dem Verfahren von Wang und Landau.
Im ersten Teil der Forschungsarbeit wird ein umfassender Überblick über Monte-Carlo-Methoden und Auswerteverfahren zur Bestimmung der Zustandsdichte sowie über verwandte Verfahren gegeben. Außerdem werden verschiedene Methoden zur Berechnung der Zustandsdichte aus Übergangsmatrizen vorgestellt und diskutiert.
Im zweiten Teil der Arbeit wird eine neue Vergleichsgrundlage für Algorithmen zur Bestimmung der Zustandsdichte erarbeitet. Dazu wird ein neues Modellsystem entwickelt, an dem verschiedene Parameter frei gewählt werden können und für das die exakte Zustandsdichte sowie die exakte Übergangsmatrix bekannt sind. Anschließend werden zwei weitere Systeme diskutiert für welche zumindest die exakte Zustandsdichte bekannt ist: das Ising Modell und das Lennard-Jones System.
Der dritte Teil der Arbeit beschäftigt sich mit numerischen Untersuchungen an einer Auswahl der vorgestellten Verfahren. Auf Basis der entwickelten Vergleichsgrundlage wird der Einfluss verschiedener Parameter auf die Qualität der berechneten Zustandsdichte quantitativ bestimmt. Es wird gezeigt, dass Übergangsmatrizen in Simulationen mit Wang-Landau-Verfahren eine wesentlich bessere Zustandsdichte liefern als das Verfahren selbst.
Anschließend werden die gewonnenen Erkenntnisse genutzt um ein neues Verfahren zu entwickeln mit welchem die Zustandsdichte mittels Minimierung der Abweichungen des detaillierten Gleichgewichts aus großen, dünnbesetzten Übergangsmatrizen gewonnen werden kann. Im Anschluss wird ein Lennard-Jones-System im großkanonischen Ensemble untersucht. Es wird gezeigt, dass durch das neue Verfahren Zustandsdichte und Dampfdruckkurve bestimmt werden können, welche qualitativ mit Referenzdaten übereinstimmen.
|
| 50 |
Ion beam processing of surfaces and interfacesLiedke, Bartosz 28 December 2011 (has links) (PDF)
Self-organization of regular surface pattern under ion beam erosion was described in detail by Navez in 1962. Several years later in 1986 Bradley and Harper (BH) published the first self-consistent theory on this phenomenon based on the competition of surface roughening described by Sigmund's sputter theory and surface smoothing by Mullins-Herring diffusion. Many papers that followed BH theory introduced other processes responsible for the surface patterning e.g. viscous flow, redeposition, phase separation, preferential sputtering, etc. The present understanding is still not sufficient to specify the dominant driving forces responsible for self-organization. 3D atomistic simulations can improve the understanding by reproducing the pattern formation with the detailed microscopic description of the driving forces. 2D simulations published so far can contribute to this understanding only partially.
A novel program package for 3D atomistic simulations called TRIDER (TRansport of Ions in matter with DEfect Relaxation), which unifies full collision cascade simulation with atomistic relaxation processes, has been developed. The collision cascades are provided by simulations based on the Binary Collision Approximation, and the relaxation processes are simulated with the 3D lattice kinetic Monte-Carlo method. This allows, without any phenomenological model, a full 3D atomistic description on experimental spatiotemporal scales. Recently discussed new mechanisms of surface patterning like ballistic mass drift or the dependence of the local morphology on sputtering yield are inherently included in our atomistic approach.
The atomistic 3D simulations do not depend so much on experimental assumptions like reported 2D simulations or continuum theories. The 3D computer experiments can even be considered as 'cleanest' possible experiments for checking continuum theories. This work aims mainly at the methodology of a novel atomistic approach, showing that: (i) In general, sputtering is not the dominant driving force responsible for the ripple formation. Processes like bulk and surface defect kinetics dominate the surface morphology evolution. Only at grazing incidence the sputtering has been found to be a direct cause of the ripple formation. Bradley and Harper theory fails in explaining the ripple dynamics because it is based on the second-order-effect 'sputtering'. However, taking into account the new mechanisms, a 'Bradley-Harper equation' with redefined parameters can be derived, which describes pattern formation satisfactorily. (ii) Kinetics of (bulk) defects has been revealed as the dominating driving force of pattern formation. Constantly created defects within the collision cascade, are responsible for local surface topography fluctuation and cause surface mass currents. The mass currents smooth the surface at normal and close to normal ion incidence angles, while ripples appear first at incidence angles larger than 40°.
The evolution of bimetallic interfaces under ion irradiation is another application of TRIDER described in this thesis. The collisional mixing is in competition with diffusion and phase separation. The irradiation with He ions is studied for two extreme cases of bimetals: (i) Irradiation of interfaces formed by immiscible elements, here Al and Pb. Ballistic interface mixing is accompanied by phase separation. Al and Pb nanoclusters show a self-ordering (banding) parallel to the interface. (ii) Irradiation of interfaces by intermetallics forming species, here Pt and Co. Well-ordered layers of phases of intermetallics appear in the sequence Pt/Pt3Co/PtCo/PtCo3/Co. The TRIDER program package has been proven to be an appropriate technique providing a complete picture of mixing mechanisms.
|
Page generated in 0.0195 seconds