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21	Elektrostatische Aufladung organischer Feldeffekttransistoren zur Verbesserung von gedruckten Schaltungen Reuter, Kay 15 November 2012 (has links) (PDF) Topic of the thesis is the production of unipolar digital circuits by means of mass-printing technologies. For this purpose accumulation-mode and depletion-mode field-effect transistors have been used. To realize depletion-mode field-effect transistors charges are injected and stored in the gate-dielectric. Consequently, the charge transport on the semiconductor-dielectric interface is influenced and the threshold voltage can be controlled. To inject charges into the dielectric different technologies have been used and will be discussed in terms of their process parameters. Finally, fully-printed digital circuits with enhanced performance are introduced. / Gegenstand der vorliegenden Arbeit ist die drucktechnische Herstellung von unipolaren digitalen Schaltungen durch eine Kombination von organischen Feldeekttransistoren vom Anreicherungs- und Verarmungstyp. Zur Realisierung von Transistoren vom Verarmungstyp werden Überschussladung in den Gate- Isolator eingebracht und gespeichert, wodurch der Ladungstransport im Transistorkanal insbesondere die Schwellspannung beeinflusst wird. Es werden verschiedene Aufladungstechnologien und deren Prozessparameter diskutiert. Abschließend werden vollständig mit Massendruckverfahren prozessierte, digitale Schaltungen mit verbesserter Signalübertragungscharakteristik vorgestellt. Organischer Feldeekttransistor Elektret Drucktechnik Digitale Schaltungen Organische Elektronik Dielektrika digital circuits printed electronics Organic Field-Effect Transistor Electret Printing Technology ddc:620 Elektret Drucktechnik Transistor Elektrostatik
22	Synthesis of Electroactive Molecules Based on Benzodioxins and Tetrathiafulvalenes Dahlstedt, Emma January 2003 (has links) <p>This thesis deals with the synthesis of electroactiveorganic compounds. The synthesis of ethylenedioxy-benzodioxinstri-dioxin and tetra-dioxin are described. These molecules wereprepared with the aim of creating donor molecules for cationicradical salts. The symmetric analogs of tri-dioxin,methylenedioxy-derivative and ethylenedioxy-naphthalene werealso synthesized. Three different cation radical salts with 2:1stoichiometries were obtained from tri-dioxin, whiletetra-dioxin merely provided polycrystalline materials.Tri-dioxin and tetra-dioxin were also successful as operationalmatrixes in PALDI-TOF.</p><p>Tetrathiafulvalenes with the2-dialkyl-amino-1,3-dithiolium-4-thiolate mesoion asbuilding-block was also synthesized. A series of doublyalkylthiol-substituted TTFs were prepared with the aim offorming self-assembly monolayers on gold surfaces in theapplication of organic thin film field-effect transistors.Film-formation for two TTFs were studied and they providedrelatively dense packed monolayers with a discrete distance ofthe TTF moiety from the gold surface.</p><p>The mesoionic compound was also for the first time used inan<i>umpolung</i>reaction. The electrophile obtained in situ bytreatment of mesoion with sulfuryl chloride was reacted with avariety of electron-rich aromatic compounds. From the receivedproducts three new arylthio-substituted TTFs weresynthesized.</p><p><b>Keywords:</b>Synthesis, Benzodioxin, Tetrathiafulvalene,Mesoion, Organic Conductor, Cation Radical Salt, CyclicVoltammetry, Electrocrystallization, Self-Assembly Monolayer,SAM, Organic Field-Effect Transistor, OFET</p> Synthesis Benzodioxin Tetrathiafulvalene Mesoion Organic Conductor Cation Radical Salt Cyclic Voltammetry Electrocrystallization Self-Assembly Monolayer SAM Organic Field-Effect Transistor OFET
23	Etude de diélectriques ferroélectriques pour une application aux transistors organiques : influence sur les performances électriques / Study of ferroelectric material as gate dielectric for organic transistor applications : impact on electrical performances Ramos, Benjamin 05 December 2017 (has links) Cette thèse porte sur l'étude d'un diélectrique de type ferroélectrique pour une application aux transistors organiques. La configuration adoptée est de type bottom-gate top- contact. Le matériau semi-conducteur utilisé est un transporteur d'électrons. Dans la première partie de ce projet, nous avons réalisé des transistors organiques à effet de champ (OFETs) avec une couche de PMMA comme diélectrique de grille. Ce matériau, très étudié et connu, permet d'avoir un composant servant de référence. Nous avons également mené une étude sur la longueur de canal, la vitesse de dépôt du semi-conducteur organique et l'épaisseur du diélectrique, en vue d'en déduire l'influence de ces grandeurs sur les performances électriques des OFETs. Après l'optimisation de ces paramètres, nous avons démontré une amélioration de la mobilité des porteurs, une augmentation du rapport Ion/Ioff, une amélioration de la capacité et une diminution des tensions d'alimentation et de seuil. Ces résultats ont été interprétés à l'aide de caractérisations électriques. Dans un second temps, le diélectrique ferroélectrique poly(vinylidenefluoride-co-trifluoroethylene) (P(VDF-TrFE)) a été ajouté au composant, afin de réaliser un diélectrique hybride avec le PMMA. Ce dernier permet de combiner les avantages de la haute permittivité relative du P(VDF-TrFE), et de la faible rugosité du film de PMMA en contact avec le semiconducteur. Une étude comparative a été effectuée avec les transistors de référence. Il en ressort, pour une épaisseur identique de diélectrique, une diminution des tensions d'alimentation et de seuil, et une amélioration de la mobilité des charges avec l'OFET implémentant le matériau ferroélectrique. La discussion de ces résultats est appuyée par des caractérisations électriques et morphologiques. / This thesis deals with the study of a ferroelectric material as gate dielectric for organic transistor applications. The configuration adopted is bottom-gate top-contact. The semiconductor used is an electron transport material. In a first part, we made organic field effect transistors (OFETs) with a layer of PMMA as a gate dielectric. This material, very studied and well known, serves as reference. We also carried out a study on the channel length, the organic semiconductor deposition rate and the dielectric thickness, in order to deduce the impact of these parameters on OFETs performances. After optimization, we have demonstrated an improvement of the mobility, on/off current ratio, capacitance and a reduction of supply and threshold voltages. These results have been interpreted using electrical characterizations. In a second step, the poly (vinylidenefluoride-co- trifluoroethylene) (P(VDF-TrFE)) ferroelectric material was added to provide a hybrid dielectric with PMMA. This OFET combine the advantages of high permittivity of P(VDF-TrFE) and low roughness of PMMA. A comparative study was carried out with reference transistors. For same dielectric thickness, a reduction of the supply and threshold voltages and an improvement of the mobility is obtained for the OFET implementing ferroelectric material. The discussion of these results is supported by electrical and morphological characterizations. Transistor organique à effet de champ OFET P(VDF-TrFE) PMMA Matériau ferroélectrique Diélectrique de grille OLET Organic field effect transistor Ferroelectrc material Gate diel
24	Fabricação e estudo das propriedades de transporte de transistores de filmes finos orgânicos / Manufacturing and study of charge transport properties of organic thin film transistors Alexandre de Castro Maciel 26 October 2012 (has links) A eletrônica digital desempenha papel essencial no desenvolvimento e manutenção dos padrões de vida em prática hoje no mundo. A peça fundamental para a criação desta era tecnológica é sem dúvidas o transistor. Com o advento de novos materiais, a busca por transistores que oferecem novas oportunidades de processamento e aplicação permitiu que uma nova área fosse criada: a eletrônica orgânica. Transistores de efeito de campo baseados em filmes finos de materiais orgânicos têm recebido grande atenção nas últimas décadas. Apresentamos um estudo experimental e teórico de transistores de efeito de campo a base de filmes finos orgânicos. Foram caracterizados transistores usando um derivado do pentaceno (TMTES-pentaceno) como camada ativa em um dispositivo feito sobre Si/SiO2. Mostramos que a inclusão do semicondutor orgânico em uma matriz polimérica isolante ajuda a manter a estabilidade termo mecânica do dispositivo. Foi desenvolvido um modelo que levasse em conta as resistências parasíticas para explicar o comportamento do transistor em função da temperatura. Também foram construídos e caracterizados transistores usando rr-P3HT como semicondutor e PMMA como isolantes. Apresentamos transistores do tipo Top-Gate e Bottom-Gate com mobilidade máxima de 7 x 10-3 cm2/V.s. Valores de razão ON/OFF de ~ 900 foram encontrados nos transistores otimizados. O comportamento dos transistores é analisado em função da temperatura e os modelos de aproximação de canal gradual e de Vissenberg-Matters foram aplicados para extração dos parâmetros de interesse. Por fim, apresentamos um modelo de corrente de canal baseado na resolução 2D numérica da equação de Poisson usando as idéias de Vissenberg-Matters para a concentração de cargas em função do potencial local. O modelo, embora ainda nos primeiros estágios de desenvolvimento, prevê a saturação da corrente nas curvas de saída simuladas sem limitações de regime de validade. / Digital electronics plays an essential role in the development and maintenance of living standards into practice in the world today. The cornerstone for the creation of this technological age is undoubtedly the transistor. With the advent of new materials, the search for transistors that offer new opportunities in processing and application allowed a new area to be created: the organic electronics. Field effect transistors based on organic thin films have received great attention in recent decades. We report an experimental and theoretical study of field effect transistors based on organic thin films. We characterized transistors manufactured using a derivative of pentacene (TMTES-pentacene) as the active layer in a device and using Si/SiO2 as gate and insulator. We show that the inclusion of the organic semiconductor in an insulating polymeric matrix helps to maintain the termo-mechanical stability of the device. A model was developed that take into account the parasitic resistances and to explain the behavior of the transistor as a function of temperature. We also present the manufacturing and characterization process of transistors using rr-P3HT as semiconductor and PMMA as insulator. We report Top-Gate and Bottom-Gate transistors with maximum mobility of 7 x 10-3 cm2/V.s. The maximun ON/OFF ratio of ~ 900 was found for the optimized transistors. The behavior of the transistors was analyzed as a function of temperature and both gradual channel approximation and Vissenberg-Matters models were applied for extracting the parameters. Finally, we present a channel current model based on the resolution of 2D numerical Poisson equation using the ideas of Vissenberg-Matters to the calculate the concentration of charges due to the local potential. The model, although still in the early stages of development, predicts the saturation current at output simulated curves with no limitation of regime validity. Filmes finos de polímeros P3HT PMMA TMTES-Pentaceno Transistor de efeito de campo orgânicos Organic field effect transistor P3HT PMMA Polymer thin films TMTES-Pentacene
25	Enhancement of n-channel Organic Field-Effect Transistor Performance through Surface Doping and Modification of the Gate Oxide by Aminosilanes Shin, Nara 22 August 2019 (has links) In this these, in order to enhance the n-channel organic field-effect transistor (OFET) performance, amino functionalized self-assembled monolayers (A-SAMs) which consist of amino groups, a well-known n-type dopant candidate, were introduced from the top of OFET surfaces and on the gate oxide surfaces. To obtain better understanding for optimization of OFET performances we attempted to elucidate the mechanism of surface doping and surface modification by A-SAMs. Both the surface doping and surface modification of the gate oxide approaches have individual pros and cons. One needs to take into account the surface energy properties of SAMs and the resulting OSC film structure and pick the most suitable method to introduce the SAM material to the OFET (either doping or oxide modification) in order to obtain optimized device performances. Our study strongly suggests that both surface doping and surface modification of the gate oxide with A-SAMs could enhance other semiconductor-based electronic device performances.:Abstract v Chapter 1. Introduction 1 Chapter 2. Theoretical Background 7 2.1. Organic Semiconductors (OSCs) 8 2.1.1. Semiconducting properties of organic molecules 8 2.1.2. Charge Transport Mechanism in OSCs 10 2.2. Organic Field-Effect Transistors (OFETs) 18 2.2.1. Operation Principle 18 2.2.2. Device Geometry of OFETs 20 2.2.3. Contacts (metal/semiconductor junction) in OFETs 21 2.2.4. Dielectric material for OFETs 23 2.2.5. Current-Voltage Characteristics of OFETs 25 2.3. Dominant contributors to OFET Performance 32 2.3.1. Molecular structure and Orientation of OSCs 32 2.3.2. Dielectric/OSC Interface 33 2.3.3. OSC/Contact Interface (Contact resistance) 35 2.3.4. Shallow and deep traps 36 2.4. Strategies to improve OFET performance 37 2.4.1. Introducing dopants to OFETs 37 2.4.2. Modification of Gate Oxide Layer with SAMs 44 Chapter 3. Experimental 51 3.1. Device Fabrication 52 3.1.1. Device type I - Substrate/ODTMS/PTCDI-C8/Au 53 3.1.2. Device type II - Substrate/ODTCS/N2200 (PNDI2OD-2T)/Au 53 3.1.3. Device type III - Substrate/SAMs/PTCDI-C8/Au 54 3.2. Surface doping process 56 3.2.1. Surface dopant – Aminosilanes (A-SAMs) 56 3.2.2. Surface doping method 56 3.3. Characterization 59 3.3.1. Material characterization 59 3.3.2. Surface-wetting characterization - Contact angle measurement 61 3.3.3. Micro-structure characterization - Atomic Force Microscopy (AFM) 62 3.3.4. Surface potential characterization – Kelvin Probe Force Microscopy (KPFM) 63 3.3.5. Molecular Structure Characterization - Grazing Incidence Wide Angle X-ray Scattering (GIWAXS) 64 3.3.6. Electrical Characterization - Current-voltage (I-V) measurement 66 Chapter 4. Result and Discussion 69 4.1. Optimization of OFETs based on PTCDI-C8 and N2200 70 4.1.1. PTCDI-C8 OFETs 70 4.1.2. N2200 OFETs 72 4.1.3. Device measurement condition 75 4.2. Investigation of Surface doping mechanism of Aminosilanes 77 4.2.1. Surface doping effect depending on the dopant processing method 77 4.2.2. Surface doping effect for different types of organic semiconductors 80 4.2.3. Surface doping effect for different types of surface dopants 89 4.2.4. Surface doping effect for different OSC grain sizes 92 4.2.5. Surface doping effect for different OSC film thicknesses 103 4.2.6. Molecular structure of the doped films identified by GIWAXS 106 4.2.7. Stability of the surface doped OFETs 107 4.2.8. Summary 111 4.3. Modification of the gate oxide with various self-assembled monolayers 112 4.3.1. The surface property of SAM-treated substrates 112 4.3.2. The relation between the OSC morphology and the field-effect mobility 115 4.3.3. The origin of the threshold voltage shift 126 4.3.4. Memristive effects in PTCDI-C8 devices on ODTMS 133 4.3.5. Summary 137 4.4. Comparison of the surface doping and the modification of the gate dielectric 138 4.4.1. The reliability factor of OFETs 138 4.4.2. The threshold voltages and field-effect mobility of OFETs 141 4.4.3. Density of Interfacial trap sites and SAM induced mobile carriers 143 4.4.4. Summary 144 Chapter 5. Conclusion 145 Bibliography 148 List of Figures 158 List of Tables 166 List of Equations 167 Acknowledgment 168 Erklärung zur Eröffnung des Promotionsverfahrens 169 info:eu-repo/classification/ddc/621.3 ddc:621.3
26	Improved Organic Semiconductor Thin-Film Formation through the Addition of Vibrations to the Solution Shearing Method Rocha, Cecilia Teixeira da 02 September 2020 (has links) In this thesis, methods for improving charge carrier mobility and deposition conditions for the solution shearing of organic semiconductors for organic field-effect transistors (OFETs) are investigated. Electrical performance for OFETs is currently still limited by the charge carrier mobility, especially when high fabrication speeds are required. In this work, adaptations are made to the solution shearing method to enhance charge carrier mobility values and to increase the deposition speed and film uniformity of semiconductor films. The solution shearing method can be easily adapted to large-scale roll-to-roll fabrication, a low-cost and high throughput fabrication process. In this work, the fabrication of OFETs with both crystalline small-molecule and donor-acceptor polymer semiconductors as the active layer is performed, and significant improvements in charge carrier mobility and film formation are achieved. Specifically, the crystalline small-molecule semiconductor TIPS-pentacene is blended with the inert dielectric polystyrene, and solution shearing parameters are optimized to obtain highly-aligned crystalline films. The thin film with optimized morphology is deposited on a very thin polymer dielectric film, demonstrating the feasibility of high-performance OFETs (effective mobility of ~1.2 cm2 V-1s-1) and an ultra-low operating voltage (~1 V) – at the time a record value. To improve crystal growth, the solution shearing method is modified to add vibrations to the liquid during the coating process. The new coating method, named “piezoshearing”, allows the application of vibrations to the liquid during deposition through the attachment of a piezo actuator to the shearing blade. The piezoshearing is implemented to enhance crystal growth during the solution shearing of crystalline materials, and tests of piezoshearing for the material 2,7-Dioctyl[1]benzothieno[3,2-b][1]benzothiophene (C8-BTBT) demonstrate that substrate coverage can be increased due to induced stick-and-slip caused by the piezoshearing. Due to the unfavorable wetting conditions of semiconducting donor-acceptor polymer solutions on the commonly used low surface energy OFET substrates, conventional solution shearing is problematic. With piezoshearing, film deposition can be significantly improved. In particular, through piezoshearing the so-called stick-and-slip instabilities are mitigated, allowing the doubling of the shearing speed, and the deposition of smooth and ultrathin films (~7 nm). In addition to enabling higher coating speeds, piezoshearing also lowers the polymer material consumption by up to ~ 70% in comparison to the conventional solution shearing method. For some materials, piezoshearing is also found to increase the charge carrier mobility in OFET devices by up to two orders of magnitude. The piezoshearing is utilized for viscous polymer solutions, which are challenging to coat, and usually, result in non-uniform films. Three donor-acceptor polymer systems were tested, and morphology changes are observed for all materials when piezoshearing is applied. For one of the polymeric solutions, an increase in crystallinity is achieved, possibly accompanied by a change in the degree of alignment of the polymer chains. For two other polymer solutions with higher molecular weight chains, very smooth films were obtained with the piezoshearing – saving 30% of material. Without the application of vibrations, such materials yield very non-uniform films, with significant thickness variations, which is unsuitable for OFET devices. In summary, this work leads to significant improvements in the solution shearing of organic semiconductor materials by adding vibrations in the kHz range to the deposition process. The effects and benefits of utilizing the piezoshearing are demonstrated, and suggestions for further improvement and studies are made.:Contents 7 1.Introduction 11 Motivation 11 Outline 12 2.Theoretical Principles of Organic Electronic Materials and Devices 13 Organic Electronics 13 Organic Semiconductors 14 Charge Transport Mechanisms in Organic Semiconductors 16 Organic Field-effect Transistors 19 Operation 19 The Metal-Semiconductor Interface 22 The Dielectric 25 Film Morphology and Charge Transport in OFETs 27 Small Molecules 27 Semicrystalline Polymers 29 3.Solution Shearing and Control of Film Morphology 33 The Solution Shearing Method 34 Capillary Flow and the Pinned Contact Line. 36 Marangoni Flow 36 Shear Flow 37 Film Formation in Solution Shearing 38 Small Molecules 38 Polymers 43 Stick-and-slip Instabilities 50 Contact Angle Hysteresis and Stick-and-slip 52 Vibration-assisted Thin-film Solution Fabrication Methods 53 Effects on a Liquid stemming from Vibration 53 Relevant Characteristics 57 Vibrations and Thin-film Formation 58 Combining the Solution Shearing and Vibrations 61 4.Experimental Methods 63 Device Fabrication 63 Substrate Preparation 63 Electrode Evaporation . 65 Piezoshearing Setup 65 Thin-film Characterization 68 Cross-Polarized Optical Microscopy 68 Grazing Incidence Wide-Angle X-ray Scattering 71 Electrical characterization 77 Characterization 77 Mobility estimation and overestimation discussion 77 5.Alignment Improvement from Blending the Small molecule TIPS- pentacene with an inert Polymer 81 Introduction 81 Optimization of film morphology for TIPS-pentacene . 82 Device Fabrication 82 Electrical Characterization .. 83 Film morphology characterization 86 Fabrication of Ultra-low-voltage Operation Devices 96 Figure of Merit of this Study 97 6.Piezoshearing of Crystalline Materials 101 Introduction 101 Piezoshearing of Pristine TIPS-pentacene 102 Film Fabrication 102 Thin-film Characterization 102 TIPS-pentacene blended with PS in Toluene: Better Performing Devices 104 Piezoshearing of C8-BTBT 105 7.Addressing Stick-and-Slip Instabilities in solution-sheared films for Introduction 109 Device Fabrication 110 The Effect of Piezoshearing on Stick-and-Slip Instabilities 111 Increasing Shearing Speed 111 Thin-film Characterization 114 Electrical Characterization 116 Energy Barriers and Overcoming them with Vibration 119 Acceleration Threshold for Mitigating Stick-and-slip 122 8.Piezoshearing of Viscous Polymer Solutions 127 Introduction 127 Device Fabrication 128 DPP4DE-TT and Film Morphology 129 DPP6DO-TT, DPP6DO-T, and Faraday Instabilities 137 Thin-film Characterization 141 Piezoshearing as a Parametric Oscillator System 145 Solid Friction 146 Viscosity 146 Transition Between Regimes 147 9.Conclusion and Outlook 149 Conclusion 149 Outlook 150 info:eu-repo/classification/ddc/621.3 ddc:621.3
27	Exploring the Use of Solution-Shearing for the Fabrication of High-Performance Organic Transistors Haase, Katherina 26 April 2021 (has links) Organic field-effect transistors (OFETs) are essential devices for the realization of novel electronic applications based on organic materials. Recent years have brought tremendous improvements regarding the organic semiconductor (OSC) with charge carrier mobilities around 10 cm²/Vs. Yet, several challenges are needed to be addressed in order to enable technologies of the future that are based on high-performance organic transistors. In this work, C8-BTBT, a high-mobility material that has gained increasing interest in the last few years, is used to prepare films with state-of-the art charge-carrier mobility and above. For this purpose, the solution-shearing method—a meniscus-guided technique that is capable to produce highly aligned, crystalline films—is applied. Based on these charge-transport layers with an estimated intrinsic mobility of up to 12 cm²/Vs, several strategies towards their exploitation for high-performance organic transistors are investigated. Among the relevant parameter, channel length, contact resistance and gate dielectric capacitance are the three aspects that are addressed. The solution-shearing method is further applied to the realization of solution-deposited polymer dielectrics. High-capacitance films with maximum values of about 280 nF/cm² are fabricated and used to produce low-voltage OFETs that can operate at -1V. In order to increase the devices’ transconductance, a novel patterning methodology to achieve sub-micrometre channel lengths is investigated. Using this technique, working devices with a channel length of 500 nm are shown. The compatibility of this process with the solution-shearing method for the fabrication of high-performance semiconducting and gate dielectric films is one of its major advantages. One of the limiting device parameters is the contact resistance as is clearly observable by the restricted current scaling that is observed for lower channel length. Hence, the interface of OSC and source/drain contacts is investigated. Even though an ultimate solution for very low contact resistance remains to be developed, important aspects for its further enhancement are deduced in this work. As an important first experimental result, this thesis describes a short-channel device architecture that is compatible with solution-shearing of high-performance films with its full potential yet to be explored in future work. / Organische Feld-Effekt Transistoren (OFETs) sind grundlegende Bestandteile für die Entwicklung neuerartiger Technologien auf der Basis von organischen Halbleitermaterialien. Insbesondere während der letzten Jahre haben diese Materialien einschlägige Verbesserungen erfahren und erreichen heute Ladungsträgermobilitäten um die 10 cm²/Vs. Um dies für die Umsetzung neuartiger Technologien zu nutzen, müssen jedoch noch einige Herausforderungen überwunden werden. Diese Arbeit leistet einen Beitrag in diese Richtung. Unter Anwendung eines der wohl populärsten Halbleitermaterialien der letzen Jahre mit der chemischen Bezeichnung C8-BTBT, wird die Herstellung von hochqualitativen Halbleiterfilmen mittels Flüssigprozessierung gezeigt. Mit der sogenannten „Solution-Shearing“ Methode – eine Abscheidetechnik, die über die Kontrolle eines trocknenden Meniskus hochkristalline und ausgerichtete Schichten erzeugen kann – ist es möglich Dünnschichtbauelemente mit abgeschätzten, intrinsischen Ladungsträgermobilitäten von bis zu 12 cm²/Vs zu erzeugen. Um diese hoch-qualitativen Filme für die Herstellung von leistungsfähigen Transistoren zu nutzen, werden mehrere relevante Parameter betrachtet, darunter die Kanallänge, der Kontaktwiderstand und das Gate-Dielektrikum. Im Speziellen wird die Abscheidung des Dielektrikums mittels der „Solution-Shearing“ Methode untersucht. Es kann gezeigt werden, dass dies für die Herstellung von qualitativ hochwertigen Filmen mit Kapazitäten bis zu 280 nF/cm² genutzt werden kann. Angewendet in OFETs erlauben diese Schichten den Betrieb bei sehr geringen Spannungen von -1V. Um die Transkonduktanz der Transistoren zu erhöhen wird zudem eine mit der „Solution-Shearing“ Methode kompatible Source/Drain-Strukturierungsmethode untersucht. Diese ermöglicht Kanallängen unter einem Mikrometer und konnte hier für die Herstellung von funktionierenden Transistoren mit einer Kanallänge bis zu nur 500 nm angewendet werden. Eine der limitierenden Transistorkenngrößen ist der Kontaktwiderstand, wie durch die abweichende Skalierung des Stromes mit verringerter Kanallänge deutlich wird. Aus diesem Grund wurde auch die Grenzfläche zwischen Halbleiter und Source/Drain-Kontakten näher untersucht. Allerdings verbleibt die Entwicklung einer effektiven Methode zur Reduzierung des Kontaktwiderstandes ein Projekt für zukünftige Untersuchungen, auch wenn die vorliegende Arbeit einige wichtige Anhaltpunkte für mögliche Strategien liefert. Als wichtiges erstes Resultat liefert die vorliegende Arbeit eine Beschreibung zur Herstellung funktionsfähiger Kurzkanal-OFETs mittels „Solution-Shearing“, deren volles Potential aber in der Zukunft weiter untersucht werden muss. info:eu-repo/classification/ddc/621.3 ddc:621.3
28	Organic Field Effect Transistor Semiconductor Blends for Advanced Electronic Devices Including UV Phototransistors and Single Walled Carbon Nanotube Enhanced Devices / OFET Semiconductor Blends for Advanced Electronic Devices Smithson, Chad 11 1900 (has links) Two major projects involving the use of solution processed blended semiconductors for organic field effect transistors (OFET) were explored. The first incorporated unsorted single walled carbon nanotubes (SWCNTs) into a diketopyrrolopyrrole-quarterthiophene (DPP-QT) semiconductor to enhance the mobility of the OFET. 2 wt % SWCNT was found to be the optimal blend ratio, nearly doubling the device mobility (0.6 to 0.98 cm^2/V·s). Beyond this ratio, the metallic content of the SWCNT’s dropped the on/off ratio below acceptable levels. When source drain metals who’s work function poorly matched that of the DPP-QT semiconductors highest occupied molecular orbital (HOMO) were used, the SWCNT could dramatically reduce the charge injection ratio with best results achieved for Al, dropping the contact resistance from 10^5 to 45 MΩ. The second project explored the addition of small molecule additives into a UV-sensitive semiconductor 2,7-dipentyl[1]benzothieno[3,2-b][1] benzothiophene (C5-BTBT) mixed with a polymethyl methacrylate (PMMA) polymer binder. We generated a C5-BTBT based phototransistor sensitive to UV-A light. The HOMO and lowest unoccupied molecular orbital (LUMO) of C5-BTBT and the various additives were measured and discovered to play a critical role in how the device operates. We discovered if an additive has a LUMO lower in energy than C5-BTBT, it can act as a charge trap for a photogenerated electron. Electron deficient additives were found to retain a trapped electron for an extended period of time, allowing the device to remain in a high current state for an extended period of time (>1 hour). This provides an opportunity for the device to be used as an optical memory system or photoswitch. The best system could detect UV-A with a Pill > 10^5 and a photoresponsivity of 40 A/W at a Pinc of 0.0427 mW/cm^2. / Thesis / Doctor of Philosophy (PhD) / An emerging field of electronics is the use of organic materials that can be solution processed, to reduce manufacturing costs and make new and interesting products. Here we used unsorted carbon nanotubes blended into the semiconductor layer of a transistor, providing a bridge for the energy mismatch between the electrodes and the semiconductor. This allowed us the freedom to choose different metals to act as our electrodes when making electronic devices. Additionally through the correct choice of semiconductor, we added device functionality, making it responsive to UV-A light. This produced a device that could act as a UV-A sensor, logic switch or memory device. These devices are air stable and solution processable, a necessity if they are to be used in real world applications. SWCNT Single Walled Carbon Nanotubes Unsorted Single Walled Carbon Nanotubes DPP-QT OFET Organic Field Effect Transistor Printed Electronics Phototransistor UV Responsive Organic Sensor Printed Sensor BTBT
29	Photochemical, Photophysical, and Electronic Properties of Fused Ring Systems with Alternating Benzene and Thiophene Units Wex, Brigitte 12 October 2005 (has links) No description available. synthesis isomer-pure benzodithiophene thienobisbenzodithiophene photochemistry, cycloaddition photoelectron spectroscopy quantum-mechanical calculations
30	Développement de transistors à effet de champ organiques et de matériaux luminescents à base de nanoclusters par impression à jet d’encre / Development of organic field effect transistors and luminescent materials based on nanoclusters by inkjet printing Robin, Malo 19 December 2017 (has links) L'objectif de cette thèse était de démontrer les potentialités de l'impression à jet d'encre pour le pilotage d'une HLED contenant des clusters métalliques phosphorescents dans le rouges, par des transistors organiques à effet de champs. Pour atteindre ce but, le projet a été divisé en deux parties : I) La fabrication et l'optimisation de transistors organiques de type n par photolithographie puis le transfert technologique vers l'impression à jet d'encre. II) Parallèlement au développement des transistors, je me suis attaché à la conception de matériaux hybrides luminescents pour la réalisation d'HLED. Pour la partie transistor, nous avons obtenu une meilleure compréhension des facteurs influençant l'injection de charges mais aussi la stabilité électrique pour un transistor de géométrie grille basse/contacts bas avec le fullerène C60 évaporé. Nous avons démontré que la résistance de contact est d'une part gouvernée par la morphologie du SCO au niveau des électrodes et d'autre part indépendante du travail de sortie du métal. En outre, nous avons vu que la stabilité électrique des transistors est fortement impactée par la nature du contact source et drain. L'optimisation des transistors fabriqués par photolithographie, qui a essentiellement consisté à modifier les interfaces, nous a permis de développer des transistors de type n performants avec des mobilités à effet de champ saturées allant jusqu'à 1,5 cm2/V.s pour une température maximum de procédé de 115 °C. Le transfert vers un transistor fabriqué par impression à jet d'encre a ensuite été effectué. Nous avons ensuite démontré que les morphologies de l'électrode de grille et de l'isolant, fabriqués par impression à jet d'encre, ont un impact négligeable sur les performances des transistors. Pour notre structure imprimée, l'injection de charges aux électrodes S/D est en fait le facteur clé pour la réalisation de transistors performants. Finalement, des matériaux phosphorescents rouges à base de cluster métalliques octaédrique de molybdène ont été développés. Le copolymère hybride résultant présentait un rendement quantique de photoluminescence de 51 %. La réalisation de l'HLED a ensuite été effectuée par combinaison d'une LED bleue commercial et du copolymère dopé avec des clusters octaédriques de molybdène pour des applications possibles en biologie ou dans l'éclairage. / The objective of this thesis was to demonstrate the potentialities of inkjet printing for driving an HLED containing red phosphorescent metallic clusters, with organic field effect transistors. To achieve this goal, the project was divided into two parts: I) The fabrication and optimization of n-type organic transistors by photolithography and then transfer to inkjet printing. II) Parallel to the development of transistors, I focused on designing luminescent hybrid materials for HLED realization. Concerning transistors, we obtained a better understanding of the factors influencing the charge injection but also the electrical stability for bottom gate/ bottom contact geometry transistor with evaporated C60 semiconductor. We have demonstrated that the contact resistance is on the one hand governed by the morphology of the SCO at the electrodes and on the other hand independent of the metal work function. In addition, we have observed that transistors electrical stability of is strongly impacted by the source and drain contact nature. The optimization of photolithography transistors, which essentially consisted of modifying the interfaces, allowed us to develop efficient n-type transistors with saturated field effect mobilities of up to 1.5 cm2/V.s for a maximal process temperature of 115 °C. The technological transfer to inkjet printed transistors was then performed. We then demonstrated that gate electrode and insulator morphologies deposited by inkjet printing, have a negligible impact on transistors performances. For our printed structure, charges injection at the S/D electrodes is in fact the key factor for high performance transistors realization. Finally, red phosphorescent materials based on molybdenum octahedral metal cluster have been developed. The resulting hybrid copolymer showed photoluminescence quantum yield up to 51%. The realization of the HLED was then carried out by combining a commercial blue LED and the copolymer doped with octahedral molybdenum clusters for possible applications in biology or lighting. Semi-Conducteur organique Transistor à effet de champ organique Fullerène C60 Impression à jet d'encre Encre SU8 Cluster octaédrique de molybdène Matériau hybride phosphorescent rouge Organic semiconductor Organic field effect transistor Fullerene C60 Inkjet printing SU8 ink Molybdenum octahedral cluster Red phosphorescent hybrid material

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