Your search keyword '"Kaschura, Felix"' showing total 16 results

1. Author Correction: Organic Power Electronics: Transistor Operation in the kA/cm2 Regime

Author

Klinger, Markus P., Fischer, Axel, Kaschura, Felix, Widmer, Johannes, Kheradmand-Boroujeni, Bahman, Ellinger, Frank, and Leo, Karl

Published

2020

2. Organic Power Electronics: Transistor Operation in the kA/cm2 Regime

Author

Klinger, Markus P., Fischer, Axel, Kaschura, Felix, Widmer, Johannes, Kheradmand-Boroujeni, Bahman, Ellinger, Frank, and Leo, Karl

Published

2017

3. Operation mechanism of high performance organic permeable base transistors with an insulated and perforated base electrode.

Author

Kaschura, Felix, Fischer, Axel, Klinger, Markus P., Duy Hai Doan, Koprucki, Thomas, Glitzky, Annegret, Kasemann, Daniel, Widmer, Johannes, and Leo, Karl

Subjects

*TRANSISTORS, *FABRICATION (Manufacturing), *ELECTRODES, *ELECTRIC potential, *INTRINSIC semiconductors

Abstract

The organic permeable base transistor is a vertical transistor architecture that enables high performance while maintaining a simple low-resolution fabrication. It has been argued that the charge transport through the nano-sized openings of the central base electrode limits the performance. Here, we demonstrate by using 3D drift-diffusion simulations that this is not the case in the relevant operation range. At low current densities, the applied base potential controls the number of charges that can pass through an opening and the opening is the current limiting factor. However, at higher current densities, charges accumulate within the openings and in front of the base insulation, allowing for an efficient lateral transport of charges towards the next opening. The on-state in the current-voltage characteristics reaches the maximum possible current given by space charge limited current transport through the intrinsic semiconductor layers. Thus, even a small effective area of the openings can drive huge current densities, and further device optimization has to focus on reducing the intrinsic layer thickness to a minimum. [ABSTRACT FROM AUTHOR]

Published

2016

4. The Organic Permeable Base Transistor:: Operation Principle and Optimizations

Author

Kaschura, Felix, Leo, Karl, Mannsfeld, Stefan, and Technische Universität Dresden

Subjects

Organischer Transistor mit permeabler Basis, Vertikaler Organischer Transistor, Drift-Diffusions-Simulation, Pentacen, Morphologie, Optimierungen, Anwendungen, Organic Permeable Base Transistor, Vertical Organic Transistor, Drift-Diffusion Simulation, Pentacene, Morphology, Optimizations, Applications, Transistor, Halbleiter, Molekül, Halbleiterbauelement, Simulation, Morphologie, Kennlinie, Anwendung, ddc:530

Abstract

Organic transistors are a core component for basically all relevant types of fully organic circuits and consumer electronics. The Organic Permeable Base Transistor (OPBT) is a transistor with a sandwich geometry like in Organic Light Emitting Diodes (OLEDs) and has a vertical current transport. Therefore, it combines simple fabrication with high performance due its short transit paths and has a fairly good chance of being used in new organic electronics applications that have to fall back to silicon transistors up to now. A detailed understanding of the operation mechanism that allows a targeted engineering without trial-and-error is required and there is a need for universal optimization techniques which require as little effort as possible. Several mechanisms that explain certain aspects of the operation are proposed in literature, but a comprehensive study that covers all transistor regimes in detail is not found. High performances have been reported for organic transistors which are, however, usually limited to certain materials. E. g., n-type C60 OPBTs are presented with excellent performance, but an adequate p-type OPBT is missing. In this thesis, the OPBT is investigated under two aspects: Firstly, drift-diffusion simulations of the OPBT are evaluated. By comparing the results from different geometry parameters, conclusions about the detailed operation mechanism can be drawn. It is discussed where charge carriers flow in the device and which parameters affect the performance. In particular, the charge carrier transmission through the permeable base layer relies on small openings. Contrary to an intuitive view, however, the size of these openings does not limit the device performance. Secondly, p-type OPBTs using pentacene as the organic semiconductor are fabricated and characterized with the aim to catch up with the performance of the n-type OPBTs. It is shown how an additional seed-layer can improve the performance by changing the morphology, how leakage currents can be defeated, and how parameters like the layer thickness should be chosen. With the combination of all presented optimization strategies, pentacene OPBTs are built that show a current density above 1000 mA/cm^2 and a current gain of 100. This makes the OPBT useful for a variety of applications, and also complementary logic circuits are possible now. The discussed optimization strategies can be extended and used as a starting point for further enhancements. Together with the deep understanding obtained from the simulations, purposeful modifications can be studied that have a great potential.:1 Introduction and Motivation 2 Theory 2.1 Organic Semiconductors 2.1.1 Organic Molecules and Solids 2.1.2 Charge Carrier Transport 2.1.3 Charge Carrier Injection 2.1.4 Doping 2.2 Organic Permeable Base Transistors 2.2.1 Structure 2.2.2 Basic Operation Principle 3 Overview of Different Transistor Architectures 3.1 Organic Field Effect Transistors 3.2 Organic Permeable Base Transistors 3.2.1 Development of the Permeable Base Transistor 3.2.2 Optimization Strategies 3.3 Comparison to Inorganic Transistors 3.4 Other Emerging Transistor Concepts 3.4.1 OSBT 3.4.2 Step-Edge OFET 3.4.3 VOFET 3.4.4 IGZO Devices 4 Experimental 4.1 Materials and their Properties 4.1.1 Pentacene 4.1.2 F6TCNNQ 4.1.3 Aluminum Oxide 4.2 Fabrication 4.2.1 Thermal Vapor Deposition 4.2.2 Chamber Details and Processing Procedure 4.2.3 Sample Structure 4.3 Characterization Methods and Tools 4.3.1 Electrical Characterization 4.3.2 Morphology 4.3.3 XPS 5 Simulations and Working Mechanism 5.1 Simulation Setup 5.1.1 Overview 5.1.2 OPBT Model 5.1.3 Drift-Diffusion Solver 5.1.4 Post-Processing of Simulation Data 5.2 Basic Concept 5.2.1 Base Sweep Regions 5.2.2 Correlation with charge carrier density and potential 5.3 Charge Carrier Accumulation 5.3.1 Accumulation at Emitter and Collector 5.3.2 Current Flow 5.3.3 Area contributing to the current flow 5.4 Current Limitation Mechanisms 5.4.1 Varying Size of the Opening 5.4.2 Channel Potential 5.4.3 Limitation of Base-Emitter Transport 5.4.4 Intrinsic Layer Variation 5.5 Opening Shapes 5.5.1 Cylindrical Opening and Symmetry 5.5.2 Truncated Cone Setup 5.6 Base Leakage Currents 5.6.1 Description of the Insulator 5.6.2 Top and Bottom Contribution 5.6.3 Validity of Calculation 5.7 Analytical Description of the OPBT base sweep 5.7.1 Description of operation regions 5.7.2 Transition Voltages and Full Characteristics 5.7.3 Comparison to Experiment 5.8 Output Characteristics 5.8.1 Saturation region 5.8.2 Linear region 5.8.3 Intrinsic Gain 5.9 Summary of Operation Mechanism 6 Nin-Devices and Structuring 6.1 Effect of Accumulation and Scalability 6.1.1 Active Area and Electrode Overlap 6.1.2 Indirect Structuring 8 Contents 6.1.3 Four-Wire Measurement 6.1.4 Pulsed Measurements 6.2 Mobility Measurement 6.2.1 Mobility Extraction from a Single IV Curve 6.2.2 Verification of the SCLC using Thickness Variations 6.3 Geometric Diode 7 Optimization of p-type Permeable Base Transistors 7.1 Introduction to p-type Devices 7.2 Characteristics of OPBTs 7.2.1 Diode characteristics 7.2.2 Base sweep 7.2.3 Output characteristics 7.3 Seed-Layer 7.3.1 Process of Opening Formation 7.3.2 Performance using different Seed-Layers 7.4 Built-in field 7.4.1 Effect on Performance 7.4.2 Explanation for the Transmission Improvement 7.5 Base Insulation 7.5.1 Importance of Base Insulation 7.5.2 Additional Insulating Layers and Positioning 7.5.3 Enhancement of Native Aluminum Oxide 7.6 Complete Optimization 7.6.1 Indirect Structuring in OPBTs 7.6.2 Combination of different Optimization Techniques 7.7 Potential of the Technology 7.7.1 Future Improvements 7.7.2 Achievable Performance 7.8 Demonstration of the Organic Permeable Base Transistor 7.8.1 Simple OLED driver 7.8.2 An Astable Oscillator using p-type OPBTs 7.8.3 An OLED Driver using n-type OPBTs controlled by Organic Solar Cells 8 Conclusion Organische Transistoren stellen eine Kernkomponente für praktisch jede Art von organischen Schaltungen und Elektronikgeräten dar. Der “Organic Permeable Base Transistor” (OPBT, dt.: Organischer Transistor mit durchlässiger Basis) ist ein Transistor mit einem Schichtaufbau wie in organischen Leuchtdioden (OLEDs) und weist einen vertikalen Stromfluss auf. Somit wird eine einfache Herstellung mit gutem Verhalten und Leistungsfähigkeit kombiniert, welche aus den kurzen Weglängen der Ladungsträger resultiert. Damit ist der OPBT bestens für neuartige organische Elektronik geeignet, wofür andernfalls auf Siliziumtransistoren zurückgegriffen werden müsste. Notwendig sind ein tiefgehendes Verständnis der Funktionsweise, welches ein zielgerichtetes Entwickeln der Technologie ohne zahlreiche Fehlversuche ermöglicht, sowie universell einsetzbare und leicht anwendbare Optimierungsstrategien. In der Literatur werden einige Mechanismen vorgeschlagen, die Teile der Funktionsweise betrachten, aber eine umfassende Untersuchung, die alle Arbeitsbereiche des Transistors abdeckt, findet sich derzeit noch nicht. Ebenso gibt es einige Veröffentlichungen, die Transistoren mit hervorragender Leistungsfähigkeit zeigen, aber meist nur mit Materialien für einen Ladungsträgertyp erzielt werden. So gibt es z.B. n-typ OPBTs auf Basis von C60, für die bisher vergleichbare p-typ OPBTs fehlen. In dieser Arbeit werden daher die folgenden beiden Aspekte des OPBT untersucht: Einerseits werden Drift-Diffusions-Simulationen von OPBTs untersucht und ausgewertet. Kennlinien und Ergebnisse von Transistoren aus verschiedenen Parametervariationen können verglichen werden und erlauben damit Rückschlüsse auf verschiedenste Aspekte der Funktionsweise. Der Fluss der Ladungsträger sowie für die Leistungsfähigkeit wichtige Parameter werden besprochen. Insbesondere sind für die Transmission von Ladungsträgern durch die Basisschicht kleine Öffnungen in dieser nötig. Die Größe dieser Öffnungen stellt jedoch entgegen einer intuitiven Vorstellung keine Begrenzung für die erreichbaren Ströme dar. Andererseits werden p-typ OPBTs auf Basis des organischen Halbleiters Pentacen hergestellt und charakterisiert. Das Ziel ist hierbei die Leistungsfähigkeit an die n-typ OPBTs anzugleichen. In dieser Arbeit wird gezeigt, wie durch eine zusätzliche Schicht die Morphologie und die Transmission verbessert werden kann, wie Leckströme reduziert werden können und welche Parameter bei der Optimierung besondere Beachtung finden sollten. Mit all den Optimierungen zusammen können Pentacen OPBTs hergestellt werden, die Stromdichten über 1000 mA/cm^2 und eine Stromverstärkung über 100 aufweisen. Damit kann der OPBT für eine Vielzahl von Anwendungen eingesetzt werden, unter anderem auch in Logik-Schaltungen zusammen mit n-typ OPBTs. Die besprochenen Optimierungen können weiterentwickelt werden und somit als Startpunkt für anschließende Verbesserungen dienen. In Verbindung mit erlangten Verständnis aus den Simulationsergebnissen können somit aussichtsreiche Veränderungen an der Struktur des OPBTs zielgerichtet eingeführt werden.:1 Introduction and Motivation 2 Theory 2.1 Organic Semiconductors 2.1.1 Organic Molecules and Solids 2.1.2 Charge Carrier Transport 2.1.3 Charge Carrier Injection 2.1.4 Doping 2.2 Organic Permeable Base Transistors 2.2.1 Structure 2.2.2 Basic Operation Principle 3 Overview of Different Transistor Architectures 3.1 Organic Field Effect Transistors 3.2 Organic Permeable Base Transistors 3.2.1 Development of the Permeable Base Transistor 3.2.2 Optimization Strategies 3.3 Comparison to Inorganic Transistors 3.4 Other Emerging Transistor Concepts 3.4.1 OSBT 3.4.2 Step-Edge OFET 3.4.3 VOFET 3.4.4 IGZO Devices 4 Experimental 4.1 Materials and their Properties 4.1.1 Pentacene 4.1.2 F6TCNNQ 4.1.3 Aluminum Oxide 4.2 Fabrication 4.2.1 Thermal Vapor Deposition 4.2.2 Chamber Details and Processing Procedure 4.2.3 Sample Structure 4.3 Characterization Methods and Tools 4.3.1 Electrical Characterization 4.3.2 Morphology 4.3.3 XPS 5 Simulations and Working Mechanism 5.1 Simulation Setup 5.1.1 Overview 5.1.2 OPBT Model 5.1.3 Drift-Diffusion Solver 5.1.4 Post-Processing of Simulation Data 5.2 Basic Concept 5.2.1 Base Sweep Regions 5.2.2 Correlation with charge carrier density and potential 5.3 Charge Carrier Accumulation 5.3.1 Accumulation at Emitter and Collector 5.3.2 Current Flow 5.3.3 Area contributing to the current flow 5.4 Current Limitation Mechanisms 5.4.1 Varying Size of the Opening 5.4.2 Channel Potential 5.4.3 Limitation of Base-Emitter Transport 5.4.4 Intrinsic Layer Variation 5.5 Opening Shapes 5.5.1 Cylindrical Opening and Symmetry 5.5.2 Truncated Cone Setup 5.6 Base Leakage Currents 5.6.1 Description of the Insulator 5.6.2 Top and Bottom Contribution 5.6.3 Validity of Calculation 5.7 Analytical Description of the OPBT base sweep 5.7.1 Description of operation regions 5.7.2 Transition Voltages and Full Characteristics 5.7.3 Comparison to Experiment 5.8 Output Characteristics 5.8.1 Saturation region 5.8.2 Linear region 5.8.3 Intrinsic Gain 5.9 Summary of Operation Mechanism 6 Nin-Devices and Structuring 6.1 Effect of Accumulation and Scalability 6.1.1 Active Area and Electrode Overlap 6.1.2 Indirect Structuring 8 Contents 6.1.3 Four-Wire Measurement 6.1.4 Pulsed Measurements 6.2 Mobility Measurement 6.2.1 Mobility Extraction from a Single IV Curve 6.2.2 Verification of the SCLC using Thickness Variations 6.3 Geometric Diode 7 Optimization of p-type Permeable Base Transistors 7.1 Introduction to p-type Devices 7.2 Characteristics of OPBTs 7.2.1 Diode characteristics 7.2.2 Base sweep 7.2.3 Output characteristics 7.3 Seed-Layer 7.3.1 Process of Opening Formation 7.3.2 Performance using different Seed-Layers 7.4 Built-in field 7.4.1 Effect on Performance 7.4.2 Explanation for the Transmission Improvement 7.5 Base Insulation 7.5.1 Importance of Base Insulation 7.5.2 Additional Insulating Layers and Positioning 7.5.3 Enhancement of Native Aluminum Oxide 7.6 Complete Optimization 7.6.1 Indirect Structuring in OPBTs 7.6.2 Combination of different Optimization Techniques 7.7 Potential of the Technology 7.7.1 Future Improvements 7.7.2 Achievable Performance 7.8 Demonstration of the Organic Permeable Base Transistor 7.8.1 Simple OLED driver 7.8.2 An Astable Oscillator using p-type OPBTs 7.8.3 An OLED Driver using n-type OPBTs controlled by Organic Solar Cells 8 Conclusion

Published

2017

5. The Organic Permeable Base Transistor:: Operation Principle and Optimizations

Author

Leo, Karl, Mannsfeld, Stefan, Technische Universität Dresden, Kaschura, Felix, Leo, Karl, Mannsfeld, Stefan, Technische Universität Dresden, and Kaschura, Felix

Abstract

Organic transistors are a core component for basically all relevant types of fully organic circuits and consumer electronics. The Organic Permeable Base Transistor (OPBT) is a transistor with a sandwich geometry like in Organic Light Emitting Diodes (OLEDs) and has a vertical current transport. Therefore, it combines simple fabrication with high performance due its short transit paths and has a fairly good chance of being used in new organic electronics applications that have to fall back to silicon transistors up to now. A detailed understanding of the operation mechanism that allows a targeted engineering without trial-and-error is required and there is a need for universal optimization techniques which require as little effort as possible. Several mechanisms that explain certain aspects of the operation are proposed in literature, but a comprehensive study that covers all transistor regimes in detail is not found. High performances have been reported for organic transistors which are, however, usually limited to certain materials. E. g., n-type C60 OPBTs are presented with excellent performance, but an adequate p-type OPBT is missing. In this thesis, the OPBT is investigated under two aspects: Firstly, drift-diffusion simulations of the OPBT are evaluated. By comparing the results from different geometry parameters, conclusions about the detailed operation mechanism can be drawn. It is discussed where charge carriers flow in the device and which parameters affect the performance. In particular, the charge carrier transmission through the permeable base layer relies on small openings. Contrary to an intuitive view, however, the size of these openings does not limit the device performance. Secondly, p-type OPBTs using pentacene as the organic semiconductor are fabricated and characterized with the aim to catch up with the performance of the n-type OPBTs. It is shown how an additional seed-layer can improve the performance by changing the morphology, how leakage cur, Organische Transistoren stellen eine Kernkomponente für praktisch jede Art von organischen Schaltungen und Elektronikgeräten dar. Der “Organic Permeable Base Transistor” (OPBT, dt.: Organischer Transistor mit durchlässiger Basis) ist ein Transistor mit einem Schichtaufbau wie in organischen Leuchtdioden (OLEDs) und weist einen vertikalen Stromfluss auf. Somit wird eine einfache Herstellung mit gutem Verhalten und Leistungsfähigkeit kombiniert, welche aus den kurzen Weglängen der Ladungsträger resultiert. Damit ist der OPBT bestens für neuartige organische Elektronik geeignet, wofür andernfalls auf Siliziumtransistoren zurückgegriffen werden müsste. Notwendig sind ein tiefgehendes Verständnis der Funktionsweise, welches ein zielgerichtetes Entwickeln der Technologie ohne zahlreiche Fehlversuche ermöglicht, sowie universell einsetzbare und leicht anwendbare Optimierungsstrategien. In der Literatur werden einige Mechanismen vorgeschlagen, die Teile der Funktionsweise betrachten, aber eine umfassende Untersuchung, die alle Arbeitsbereiche des Transistors abdeckt, findet sich derzeit noch nicht. Ebenso gibt es einige Veröffentlichungen, die Transistoren mit hervorragender Leistungsfähigkeit zeigen, aber meist nur mit Materialien für einen Ladungsträgertyp erzielt werden. So gibt es z.B. n-typ OPBTs auf Basis von C60, für die bisher vergleichbare p-typ OPBTs fehlen. In dieser Arbeit werden daher die folgenden beiden Aspekte des OPBT untersucht: Einerseits werden Drift-Diffusions-Simulationen von OPBTs untersucht und ausgewertet. Kennlinien und Ergebnisse von Transistoren aus verschiedenen Parametervariationen können verglichen werden und erlauben damit Rückschlüsse auf verschiedenste Aspekte der Funktionsweise. Der Fluss der Ladungsträger sowie für die Leistungsfähigkeit wichtige Parameter werden besprochen. Insbesondere sind für die Transmission von Ladungsträgern durch die Basisschicht kleine Öffnungen in dieser nötig. Die Größe dieser Öffnungen stellt jedoch entgegen e

Published

2017

6. Nonlinear Contact Effects in Staggered Thin-Film Transistors

Author

Fischer, Axel, primary, Zündorf, Hilke, additional, Kaschura, Felix, additional, Widmer, Johannes, additional, Leo, Karl, additional, Kraft, Ulrike, additional, and Klauk, Hagen, additional

Published

2017

7. Organic permeable-base transistors - superb power efficiency at highest frequencies (Conference Presentation)

Author

Klinger, Markus P., primary, Fischer, Axel, additional, Kaschura, Felix, additional, Scholz, Reinhard, additional, Lüssem, Björn, additional, Kheradmand-Boroujeni, Bahman, additional, Ellinger, Frank, additional, Kasemann, Daniel, additional, and Leo, Karl, additional

Published

2016

8. Organic Permeable Base Transistors for Flexible Electronic Circuits

Author

Dollinger, Felix, primary, Klinger, Markus, additional, Fischer, Axel, additional, Kaschura, Felix, additional, Widmer, Johannes, additional, and Leo, Karl, additional

Published

2016

9. Ambipolar organic permeable base transistors

Author

Kaschura, Felix, Fischer, Axel, Kasemann, Daniel, Leo, Karl, Kaschura, Felix, Fischer, Axel, Kasemann, Daniel, and Leo, Karl

Abstract

Organic transistors with vertical current transport like the Permeable Base Transistor (PBT) show a high performance while allowing for an easy fabrication on the device level. For a simple implementation on a circuit level, ambipolar transistors, providing the functionality of n-type as well as p-type devices, have a benefit for complementary logic. This requires transistors where electrons and holes are present. Here, we investigate a potential concept of bipolar current transport in PBTs. In our device structure, we use the base electrode to control the current flow, but also to investigate the charge carrier transport. The ambipolar organic PBT achieves a charge carrier transmission of 88% and a current density above 200mA=cm². Additionally, we show that recombination near the base is required in an ambipolar PBT for a good performance.

Published

2015

10. Transistors: Advanced Organic Permeable-Base Transistor with Superior Performance (Adv. Mater. 47/2015)

Author

Klinger, Markus P., primary, Fischer, Axel, additional, Kaschura, Felix, additional, Scholz, Reinhard, additional, Lüssem, Björn, additional, Kheradmand-Boroujeni, Bahman, additional, Ellinger, Frank, additional, Kasemann, Daniel, additional, and Leo, Karl, additional

Published

2015

11. Advanced Organic Permeable-Base Transistor with Superior Performance

Author

Klinger, Markus P., primary, Fischer, Axel, additional, Kaschura, Felix, additional, Scholz, Reinhard, additional, Lüssem, Björn, additional, Kheradmand-Boroujeni, Bahman, additional, Ellinger, Frank, additional, Kasemann, Daniel, additional, and Leo, Karl, additional

Published

2015

12. Ambipolar organic permeable base transistors

Author

Kaschura, Felix, additional, Fischer, Axel, additional, Kasemann, Daniel, additional, and Leo, Karl, additional

Published

2015

13. Controlling morphology: A vertical organic transistor with a self-structured permeable base using the bottom electrode as seed layer

Author

Kaschura, Felix, primary, Fischer, Axel, additional, Kasemann, Daniel, additional, Leo, Karl, additional, and Lüssem, Björn, additional

Published

2015

14. Organic permeable-base transistors - superb power efficiency at highest frequencies (Conference Presentation)

Author

McCulloch, Iain, Jurchescu, Oana D., Klinger, Markus P., Fischer, Axel, Kaschura, Felix, Scholz, Reinhard, Lüssem, Björn, Kheradmand-Boroujeni, Bahman, Ellinger, Frank, Kasemann, Daniel, and Leo, Karl

Published

2016

15. Organic Power Electronics: Transistor Operation in the kA/cm2 Regime.

Author

Klinger, Markus P., Fischer, Axel, Kaschura, Felix, Widmer, Johannes, Kheradmand-Boroujeni, Bahman, Ellinger, Frank, and Leo, Karl

Abstract

In spite of interesting features as flexibility, organic thin-film transistors have commercially lagged behind due to the low mobilities of organic semiconductors associated with hopping transport. Furthermore, organic transistors usually have much larger channel lengths than their inorganic counterparts since high-resolution structuring is not available in low-cost production schemes. Here, we present an organic permeable-base transistor (OPBT) which, despite extremely simple processing without any high-resolution structuring, achieve a performance beyond what has so far been possible using organic semiconductors. With current densities above 1 kA cm−2 and switching speeds towards 100 MHz, they open the field of organic power electronics. Finding the physical limits and an effective mobility of only 0.06 cm2 V−1 s−1, this OPBT device architecture has much more potential if new materials optimized for its geometry will be developed. [ABSTRACT FROM AUTHOR]

Published

2017

16. Ambipolar organic permeable base transistors

Author

McCulloch, Iain, Jurchescu, Oana D., Kymissis, Ioannis, Shinar, Ruth, Torsi, Luisa, Kaschura, Felix, Fischer, Axel, Kasemann, Daniel, and Leo, Karl

Published

2015