Elementary processes in layers of electron transporting Donor-acceptor copolymers : investigation of charge transport and application to organic solar cells

Schubert, Marcel

January 2014

Donor-acceptor (D-A) copolymers have revolutionized the field of organic electronics over the last decade. Comprised of a electron rich and an electron deficient molecular unit, these copolymers facilitate the systematic modification of the material's optoelectronic properties. The ability to tune the optical band gap and to optimize the molecular frontier orbitals as well as the manifold of structural sites that enable chemical modifications has created a tremendous variety of copolymer structures. Today, these materials reach or even exceed the performance of amorphous inorganic semiconductors. Most impressively, the charge carrier mobility of D-A copolymers has been pushed to the technologically important value of 10 cm^{2}V^{-1}s^{-1}. Furthermore, owed to their enormous variability they are the material of choice for the donor component in organic solar cells, which have recently surpassed the efficiency threshold of 10%. Because of the great number of available D-A copolymers and due to their fast chemical evolution, there is a significant lack of understanding of the fundamental physical properties of these materials. Furthermore, the complex chemical and electronic structure of D-A copolymers in combination with their semi-crystalline morphology impede a straightforward identification of the microscopic origin of their superior performance. In this thesis, two aspects of prototype D-A copolymers were analysed. These are the investigation of electron transport in several copolymers and the application of low band gap copolymers as acceptor component in organic solar cells. In the first part, the investigation of a series of chemically modified fluorene-based copolymers is presented. The charge carrier mobility varies strongly between the different derivatives, although only moderate structural changes on the copolymers structure were made. Furthermore, rather unusual photocurrent transients were observed for one of the copolymers. Numerical simulations of the experimental results reveal that this behavior arises from a severe trapping of electrons in an exponential distribution of trap states. Based on the comparison of simulation and experiment, the general impact of charge carrier trapping on the shape of photo-CELIV and time-of-flight transients is discussed. In addition, the high performance naphthalenediimide (NDI)-based copolymer P(NDI2OD-T2) was characterized. It is shown that the copolymer posses one of the highest electron mobilities reported so far, which makes it attractive to be used as the electron accepting component in organic photovoltaic cells.par Solar cells were prepared from two NDI-containing copolymers, blended with the hole transporting polymer P3HT. I demonstrate that the use of appropriate, high boiling point solvents can significantly increase the power conversion efficiency of these devices. Spectroscopic studies reveal that the pre-aggregation of the copolymers is suppressed in these solvents, which has a strong impact on the blend morphology. Finally, a systematic study of P3HT:P(NDI2OD-T2) blends is presented, which quantifies the processes that limit the efficiency of devices. The major loss channel for excited states was determined by transient and steady state spectroscopic investigations: the majority of initially generated electron-hole pairs is annihilated by an ultrafast geminate recombination process. Furthermore, exciton self-trapping in P(NDI2OD-T2) domains account for an additional reduction of the efficiency. The correlation of the photocurrent to microscopic morphology parameters was used to disclose the factors that limit the charge generation efficiency. Our results suggest that the orientation of the donor and acceptor crystallites relative to each other represents the main factor that determines the free charge carrier yield in this material system. This provides an explanation for the overall low efficiencies that are generally observed in all-polymer solar cells. / Donator-Akzeptor (D-A) Copolymere haben das Feld der organischen Elektronik revolutioniert. Bestehend aus einer elektronen-reichen und einer elektronen-armen molekularen Einheit,ermöglichen diese Polymere die systematische Anpassung ihrer optischen und elektronischen Eigenschaften. Zu diesen zählen insbesondere die optische Bandlücke und die Lage der Energiezustände. Dabei lassen sie sich sehr vielseitig chemisch modifizieren, was zu einer imensen Anzahl an unterschiedlichen Polymerstrukturen geführt hat. Dies hat entscheidend dazu beigetragen, dass D-A-Copolymere heute in Bezug auf ihren Ladungstransport die Effizienz von anorganischen Halbleitern erreichen oder bereits übetreffen. Des Weiteren lassen sich diese Materialien auch hervorragend in Organischen Solarzellen verwenden, welche jüngst eine Effizienz von über 10% überschritten haben. Als Folge der beträchtlichen Anzahl an unterschiedlichen D-A-Copolymeren konnte das physikalische Verständnis ihrer Eigenschaften bisher nicht mit dieser rasanten Entwicklung Schritt halten. Dies liegt nicht zuletzt an der komplexen chemischen und mikroskopischen Struktur im Film, in welchem die Polymere in einem teil-kristallinen Zustand vorliegen. Um ein besseres Verständnis der grundlegenden Funktionsweise zu erlangen, habe ich in meiner Arbeit sowohl den Ladungstransport als auch die photovoltaischen Eigenschaften einer Reihe von prototypischen, elektronen-transportierenden D-A Copolymeren beleuchtet. Im ersten Teil wurden Copolymere mit geringfügigen chemischen Variationen untersucht. Diese Variationen führen zu einer starken Änderung des Ladungstransportverhaltens. Besonders auffällig waren hier die Ergebnisse eines Polymers, welches sehr ungewöhnliche transiente Strom-Charakteristiken zeigte. Die nähere Untersuchung ergab, dass in diesem Material elektrisch aktive Fallenzustände existieren. Dieser Effekt wurde dann benutzt um den Einfluss solcher Fallen auf transiente Messung im Allgemeinen zu beschreiben. Zusätzlich wurde der Elektronentransport in einem neuartigen Copolymer untersucht, welche die bis dato größte gemesse Elektronenmobilität für konjugierte Polymere zeigte. Darauf basierend wurde versucht, die neuartigen Copolymere als Akzeptoren in Organischen Solarzellen zu implementieren. Die Optimierung dieser Zellen erwies sich jedoch als schwierig, konnte aber erreicht werden, indem die Lösungseigenschaften der Copolymere untersucht und systematisch gesteuert wurden. Im Weiteren werden umfangreiche Untersuchungen zu den relevanten Verlustprozessen gezeigt. Besonders hervorzuheben ist hier die Beobachtung, dass hohe Effizienzen nur bei einer coplanaren Packung der Donator/Akzeptor-Kristalle erreicht werden können. Diese Struktureigenschaft wird hier zum ersten Mal beschrieben und stellt einen wichtigen Erkenntnisgewinn zum Verständnis von Polymersolarzellen dar.

Organische Solarzellen

Ladungstransport

Donator-Akzeptor-Copolymere

Alternative Akzeptorpolymere

Polymer-Kristalle

organic solar cells

charge transport

Donor-acceptor copolymers

alternative electron acceptors

polymer crystal orientation

Physics

Charge transport limits and electrical dopant activation in transparent conductive (Al,Ga):ZnO and Nb:TiO2 thin films prepared by reactive magnetron sputtering

Cornelius, Steffen

01 December 2014

Transparent conductive oxides (TCOs) are key functional materials in existing and future electro-optical devices in the fields of energy efficiency, energy generation and information technology. The main application of TCOs is as thin films transparent electrodes where a combination of maximum electrical conductivity and transmittance in the visible to nearinfrared spectral range is required. However, due to the interdependence of the optical properties and the free electron density and mobility, respectively, these requirements cannot be achieved simultaneously in degenerately doped wide band-gap oxide semiconductors. Therefore, a detailed understanding of the mechanisms governing the generation of free charge carriers by extrinsic doping and the charge transport in these materials is essential for further development of high performance TCOs and corresponding deposition methods. The present work is aimed at a comprehensive investigation of the electrical, optical and structural properties as well as the elemental composition of (Al,Ga) doped ZnO and Nb doped TiO2 thin films prepared by pulsed DC reactive magnetron sputtering. The evolution of the film properties is studied in dependence of various deposition parameters through a combination of characterization techniques including Hall-effect, spectroscopic ellipsometry, spectral photometry, X-ray diffraction, X-ray near edge absorption, Rutherford backscattering spectrometry and particle induced X-ray emission. This approach resulted in the development of an alternative process control method based on the material specific current-voltage pressure characteristics of the reactive magnetron discharge which allows to precisely control the oxygen deficiency of the sputter deposited films. Based on the experimental data, models have been established that describe the room temperature charge transport properties and the dielectric function of the obtained ZnO and TiO2 based transparent conductors. On the one hand, these findings allow the prediction of material specific electron mobility limits by identifying the dominating charge carrier scattering mechanisms. On the other hand, new insight is gained into the origin of the observed transition from highly conductive to electrically insulating ZnO layers upon the incorporation of increasing concentrations of Al at elevated growth temperatures. Moreover, the Al and Ga dopant activation in ZnO have been quantified systematically for a wide range of Al concentrations and deposition conditions. A direct comparison of the Ga and Al doping efficiency demonstrates that Ga is a more efficient electron donor in ZnO. Further, it has been shown that high free electron mobilities in polycrystalline and epitaxial Nb:TiO2 layers can be achieved by reactive magnetron sputtering of TiNb alloy targets. The suppression of rutile phase formation and the control of the Nb dopant activation by fine tuning the oxygen deficiency have been identified as crucial for the growth of high quality TiO2 based TCO layers.

transparent conductive oxide

magnetron sputtering

titanium oxide

anatase

degenerate semiconductor

zinc oxide

charge transport

mobility

doping

dopant activation

ddc:530

rvk:UP 7500

Strong interactions in alkaline-earth Rydberg ensembles

Mukherjee, Rick

17 December 2014

Ultra-cold atoms in optical lattices provide a versatile and robust platform to study fundamental condensed-matter physics problems and have applications in quantum optics as well as quantum information processing. For many of these applications, Rydberg atoms (atoms excited to large principal quantum numbers) are ideal due to its long coherence times and strong interactions. However, one of the pre-requisite for such applications is identical confinement of ground state atoms with Rydberg atoms. This is challenging for conventionally used alkali atoms. In this thesis, I discuss the potential of using alkaline-earth Rydberg atoms for many-body physics by implementing simultaneous trapping for the relevant internal states. In particular, I consider a scheme for generating multi-particle entanglement and explore charge transport in a one dimensional atomic lattice.

Rydberg atoms

optical lattice

alkaline-earth atoms

strontium

entanglement

charge transport

spins

many-body systems

magic lattice

ddc:530

rvk:UL 1000

Theoretical characterization of charge transport in organic molecular crystals

Sánchez-Carrera, Roel S.

25 August 2008

In this thesis, a first-principles methodology to investigate the impact of electron-phonon interactions on the charge-carrier mobilities in organic molecular crystals has been developed. Well-known organic materials such as oligoacene and oligothienoacene derivatives were studied in detail. The nature of the intramolecular vibronic coupling in oligoacenes and oligothienoacenes was studied using an approach that combines high-resolution gas-phase photo-electron spectroscopy measurements with first-principles quantum-mechanical calculations. The electron interactions with optical phonons in oligoacene single crystals were investigated using both density functional theory and empirical force field methods. The low-frequency optical modes are found to play a significant role in dictating the temperature dependence of the charge-transport properties in the oligoacene crystals. The microscopic charge-transport parameters in the pentathienoacene, 1,4-diiodobenzene, and 2,6-diiodo-dithieno[3,2-<i>b</i>:2',3'-<i>d</i>]thiophene crystals were also investigated. It was found that the intrinsic charge transport properties in the pentathienoacene crystal might be higher than that in two benchmark high-mobility organic crystals, i.e., pentacene and sexithienyl. For 1,4-diiodobenzene crystal, a detailed quantum-mechanical study indicated that its high mobility is primarily associated with the iodine atoms. In the 2,6-diiododithieno[3,2-<i>b</i>:2',3'-<i>d</i>]thiophene crystal, the main source of electronic interactions were found along the π-stacking direction. For negatively charged carriers, the halogen-functionalized molecular crystals show a very large polaron binding energy, which suggests significantly low charge-transport mobility for electrons.

Electron-phonon coupling

Charge transport

Organic molecular crystals

Electronic coupling

Organic electronics

Charge-carrier mobilities

Charge transfer

Molecular crystals

Organic compounds

Organic semiconductors

Electron-phonon interactions

Étude et optimisation de l'absorption optique et du transport électronique dans les cellules photovoltaïques à base de nanofils / Study and optimization of the optical absorptance and electrical transport in photovoltaic nanowire based solar cells

Michallon, Jérôme

26 January 2015

La conversion photovoltaïque est un procédé très attractif pour la fourniture d’énergie propre et renouvelable. Cette filière est en plein essor grâce à une réduction constante des coûts de revient et des politiques incitatives de nombreux pays. Pourtant, l’ensemble des panneaux photovoltaïques installés ne produit qu’une faible part de la consommation mondiale en électricité. Les récents développements technologiques dans l’industrie photovoltaïque se sont surtout concentrés sur les cellules dites de seconde génération, à savoir les couches minces à base de CIGS, CdTe, a-Si, a-SiGe. Cette filière permet la fourniture d’électricité à coût inférieur à la technologie standard silicium, mais les rendements de conversion demeurent encore faibles, ce qui nécessite de larges surfaces disponibles. Il est à noter notamment que les cellules couches minces à base de matériaux semiconducteurs à gap direct comme le CIGS et le CdTe sont en plein essor puisqu’ils profitent en particulier d’une absorption accrue par rapport au silicium ; toutefois, ces matériaux sont présents en quantité limitée à la surface de la planète (In, Te). Dans ce contexte, les cellules à base de nanofils constituent une solution intéressante aux problèmes de l’absorption de la lumière, du transport et de la séparation des porteurs de charge photo-générés mais aussi de la quantité de matière utilisée. En effet, en utilisant une jonction radiale (i.e. entourant le nanofil), il est possible de séparer l’absorption de la lumière ( liée notamment à la longueur du nanofil) de la collecte des porteurs de charge (qui dépend du diamètre des nanofils). L’intérêt de ces structures réside également dans les propriétés de base des nanofils : la relaxation élastique favorable sur leur surface latérale ouvre le champ au dépôt de nanofils par hétéro-épitaxie sur tout type de substrat alors que la faible densité de défauts étendus en leur sein est propice à un transport efficace des porteurs de charges. Ainsi, la possibilité de réaliser des nanofils sur substrat souple en réduisant de manière importante la quantité de matière utilisée par rapport à une cellule en silicium cristallin massif peut être envisagée. Plusieurs laboratoires grenoblois ont déjà une expertise dans le domaine de la croissance des nanofils. Cette thèse a pour but de réaliser une analyse expérimentale approfondie des propriétés optoélectroniques des nanofils (par des mesures de réflectivité, de durée de vie des porteurs minoritaires et de recombinaisons en surface et aux interfaces) combinée à des simulations optiques (de type RCWA ou FDTD) et électriques (TCAD). L’objectif ultime étant de concevoir et de développer des cellules à base de nanofils de silicium et de ZnO/CdTe. Des démonstrateurs seront réalisés sur la base des simulations électro-optiques. Pour cela, les moyens d’élaboration, de caractérisation et de technologie des différents laboratoires et entités, ainsi que les compétences associées, seront mis en commun pour accompagner les travaux du doctorant. / Photovoltaic energy is a very attractive way to produce renewable energy. The current increase in the photovoltaic energy production mainly takes advantage of the continuous decrease in the solar cell cost as well as to incentive policy. However, installed photovoltaic panels only contribute to a very small part of the global electricity production. Therefore, important technological developments are dedicated to the second generation of solar cells (i.e. thin film solar cells) in order to reduce more their manufacturing cost despite the resulting lower conversion efficiency owing to a weaker structural and optical material quality. One alternative way to increase the solar cell efficiency is to fabricate nanowire-based solar cells since they may benefit from a higher light absorption and carrier collection efficiency. The light absorption is actually increased thanks to the high surface/volume ratio of nanowires but also to light trapping related to the nanowire length. Furthermore, the collection of minority charge carriers is more efficient in radial structures (i.e. core-shell structures) since the nanowire diameter is very small. This PhD thesis aims at investigating the optoelectronic properties of silicon and ZnO/CdTe nanowires (absorption, lifetime of minority charge carriers, bulk and surface recombination…) in order to design an optimised nanowire-based solar cell structure. Electromagnetic simulations will be first performed to define the best nanowire geometry for the absorbance, and then compared to experimental measurements of the absorption coefficient. Electrical characterisations (lifetime measurements, surface recombination…) will be also achieved to analyse the structural quality and to simulate the solar cell electrical properties. Some prototypes of optimised solar cells will eventually be fabricated.

Cellule photovoltaïque

Réseaux de nanofils

ZnO/CdTe

C-Si/a-Si

Modes optiques

Transport de charges

Solar cell

Nanowire arrays

ZnO/CdTe

C-Si/a-Si

Optical modes

Charge transport

620

Contributions aux propriétés de transport d'un système à N Corps / Contributions to the transport properties of many body systems

Silva, Fernanda Deus da

11 March 2015

Nous étudions plusieurs problémes reliés aux propriétés de transport dans les systèmes corrélés. La thèse contient 3 parties distinctes, chacune d'entre elles décrivant un aspect particulier. Nous avons obtenu dans chacun des cas des résultats qui permettent une meilleure compréhension du transport. Nous étudions l'effet de la dissipation et d'une perturbation extérieure dépendant du temps sur le diagramme de phases d'un systèmes à N corps à température nulle et à température finie. En présence de perturbation dépendant du temps, la dissipation joue un rôle important dans l'évolution vers un état stable indépendant du temps. Nous utilisons le formalisme de Keldysh dans l'approximation adiabatique qui permet d'étudier le diagramme de phases du système en fonction de parameter et de la température. Dans la 2ième partie, nous étudions un concept important pour la physique des systèmes métalliques à plusieurs bandes, le concept d'hybridation, et la façon dont l'hybridation affecte la supraconductivité du métal. De façon générale, une hybridation dépendante ou non du vecteur d'onde k a tendance à détruire la supraconductivité. Nous montrons dans ce chapitre qu'une hybridation antisymétrique a l'effet inverse et renforce la supraconductivité. Nous montrons que si l'hybridation est antisymétrique, la supraconductivité a des propriétés non-triviales. Nous proposons que dans un tel système, il puisse exister des fermions de Majorana, même en l'absence de couplage spin-orbite. Le dernier chapitre de la thèse porte sur les effets du couplage spin-orbite sur le transport dans les nanostructures magnétiques. Dans les nanostructures, le couplage spin-orbite joue un rôle important en raison de la brisure de symmétrie à la surface ou aux interfaces. En particulier, nous étudions l'effet de l'interaction Dzyaloshinskii-Moriya (DM) sur le transport de spin dans un système tri-couche. Nous montrons qu'il existe une interaction DM entre les moments des couches et les électrons de conduction, et l'influence de cette interaction sur le transport est étudiée dans un modèle simplifié ou chaque couche est représentée par un point. / We study some important problems related to the transport properties of many body systems. It is divided in three parts, each one focusing in a specific topic. We obtain relevant results that improve our understanding of these systems. We investigate the effect of dissipation and time-dependent external sources, in the phase diagram of a many body system at zero and finite temperature. In the presence of time-dependent perturbations, dissipation is essential for the system to attain a steady, time independent state. In order to treat this time dependent problem, we use a Keldysh approach within an adiabatic approximation that allows us to study the phase diagram of this system as a function of the parameters of the system and temperature. We also discuss the nature of the quantum phase transitions of the system. Next, we study an important concept in the physics of metallic multi-band systems, that of hybridization, and how it affects the superconducting properties of a material. A constant or symmetric $k$-dependent hybridization in general act in detriment of superconductivity. We show here that when hybridization between orbitals in different sites assumes an anti-symmetric character having odd-parity it {it{enhances}} superconductivity. The antisymmetric hybridization in a problem study in this thesis (present in Chapter 3) allow us to propose a new system where it is possible to investigate Majorana fermions, even in absence of spin-orbit interactions. In the last part of this thesis we study the effect of spin-orbit coupling (SOC) on transport properties in magnetic nanostructures. In this system SOC plays an important role, because surfaces (or interfaces) introduce symmetry breaking which is a source of spin-orbit interaction. We study the role of Dzyaloshinshkii-Moriya (DM) interaction on spin-transport in a 3 layer system. We show that there is a DM interaction between magnetics ions in the layers and spin of conduction electrons. We study the influence of this DM interaction on transport within a simple model where each layer is represented by a point.

Systèmes fortement corrélés

Transport de charge et de spin

Point critique quantique

Spintronique

Strongly correlated electronic systems

Spin and charge transport

Quantum critical point

Spintronics

530

Transport náboje v polovodičových detektorech záření / Charge transport in semiconducting radiation detectors

Pipek, Jindřich

January 2018

This thesis is focused on study of charge transport in semiconducting radiation detectors. Theoretical calculations of current waveforms based on continuity equation and drift-diffusion equation are done. Useful approximations of current waveforms for detector with shallow electron trap are discussed. Monte Carlo simulation of the current waveforms is proposed and applied to fit experimental current waveforms measured using laser-induced transient current technique and for evaluation of charge transport parameters of the detector such as electric field profile, trapping and detrapping time of traps, drift mobility and other parameters. Detectors prepared from semi-insulating GaAs and CdZnTe single crystals are tested using electrical, spectroscopic and optical characterization techniques.

Modélisation des relations structure / propriétés de transport de charge dans les matériaux pour l'électronique organique / Structure/charge transport relationships in molecular and polymeric materials for organic electronics through atomistic modeling

Gali, Sai Manoj

10 October 2017

Les avancées technologiques et l'intégration massive de dispositifs électroniques nanométriques dans les objets de notre vie quotidienne ont généré une explosion des coûts de R&D, de conception et de production, ainsi que des inquiétudes sociétales quant à l'impact environnemental des déchets électroniques. En raison de procédés de production moins coûteux et à faible impact environnemental, de leur souplesse d’utilisation et de la possibilité de moduler leurs propriétés à l’infini, les molécules et polymères organiques constituent une classe de matériaux prometteuse pour la mise au point de nouveaux dispositifs électroniques. L’électronique organique couvre ainsi un vaste domaine d’applications, parmi lesquelles se trouvent les diodes électroluminescentes, les transistors à effet de champ ou les cellules photovoltaïques. Bien que la plupart de ces dispositifs soient déjà commercialisés, les processus gouvernant leur efficacité à l’échelle atomique sont loin d’être entièrement compris et maîtrisés. C’est en particulier le cas des processus de transport de charge, qui interviennent dans tous ces dispositifs.L'objectif de cette thèse est d’apporter une compréhension fondamentale des processus de transport de charge dans les semiconducteurs organiques, à partir d'approches théoriques combinant dynamique moléculaire, calculs quantiques et simulations Monte Carlo. Ce travail est développé suivant trois axes principaux:(I) Etude des relations liant l'organisation structurale et les propriétés de transport de cristaux moléculaires, et du rôle des fluctuations énergétiques dans des matériaux polymères amorphes. Des simulations Monte Carlo Cinétique (KMC) couplés au formalisme de Marcus-Levich-Jortner pour le calcul des taux de transfert ont été effectués afin de déterminer les mobilités des électrons et des trous au sein de dix structures cristallines de dérivés phtalocyanines. Dans une deuxième étude, une approche similaire a été employée afin de décrire les propriétés de transport de charge au sein d'un copolymère amorphe de fluorène-triphénylamine, ainsi que l'impact des fluctuations énergétiques sur ces dernières. La méthodologie développée permet d'obtenir, pour un faible coût calculatoire, une estimation semi-quantitative des mobilités des porteurs de charge dans ce type de système.(II) Etude de l'impact de contraintes mécaniques sur les propriétés de transport de matériaux organiques cristallins. La réponse électronique et les propriétés de transport de matériaux organiques soumis à une contrainte mécanique ont été étudiés à l'aide de simulations de dynamique moléculaire et de calculs DFT. Le rubrène cristallin et ses polymorphes, ainsi que les dérivés du BTBT, ont été considérés pour cette étude, qui révèle un couplage électromécanique inhabituel entre les différents axes cristallographiques. Les résultats démontrent en particulier que l'anisotropie structurale des monocristaux organiques conduit à une anisotropie du couplage électromécanique.(III) Etude du rôle du polyélectrolyte dans la conductivité des complexes conducteurs. Le polystyrène substitué par du bis(sulfonyl)imide est utilisé comme un contre-ion et un dopant dans les complexes conducteurs PEDOT-polyélectrolytes. En complément des analyses expérimentales, des simulations de dynamique moléculaire couplées à des calculs DFT ont été effectuées dans ces systèmes afin d'analyser l'impact de la conformation et de l'état de protonation du polyélectrolyte sur la conductivité du complexe formé avec le PEDOT.Les études décrites ci-dessus, réalisées sur différents types de matériaux en couplant différents types d'approches théoriques, ont permis d'apporter une compréhension fondamentale des propriétés de transport dans les semiconducteurs organiques. Elles mettent en particulier en évidence l'impact de l'organisation structurale, des interactions intermoléculaires et de l'application de contraintes mécaniques sur la mobilité des porteurs de charges dans ces matériaux. / With the advancement of technology, miniaturized electronic devices are progressively integrated into our everyday lives, generating concerns about cost, efficiency and environmental impact of electronic waste. Organic electronics offers a tangible solution paving the way for low-cost, flexible, transparent and environment friendly devices. However, improving the functionalities of organic (opto) electronic devices such as light emitting diodes and photovoltaics still poses technological challenges due to factors like low efficiencies, performance stability, flexibility etc. Although more and more organic materials are being developed to meet these challenges, one of the fundamental concerns still arises from the lack of established protocols that correlate the inherent properties of organic materials like the chemical structure, molecular conformation, supra-molecular arrangement to their resulting charge-transport characteristics.In this context, this thesis addresses the prediction of charge transport properties of organic semiconductors through theoretical and computational studies at the atomistic scale, developed along three main axes :(I) Structure-charge transport relationships of crystalline organic materials and the role of energetic fluctuations in amorphous polymeric organic semiconductors. Kinetic Monte-Carlo (KMC) studies employing the Marcus-Levich-Jortner rate formalism are performed on ten crystalline Group IV phthalocyanine derivatives and trends linking the crystalline arrangement to the anisotropic mobility of electrons and holes are obtained. Subsequently, KMC simulations based on the simpler Marcus formalism are performed on an amorphous semiconducting fluorene-triphenylamine (TFB) copolymer, to highlight the impact of energetic fluctuations on charge transport characteristics. A methodology is proposed to include these fluctuations towards providing a semi-quantitative estimate of charge-carrier mobilities at reduced computational cost.(II) Impact of a mechanical strain on the electronic and charge transport properties of crystalline organic materials. Crystalline rubrene and its polymorphs, as well as BTBT derivatives (well studied high mobility organic materials) are subjected to mechanical strain and their electronic response is analyzed. Employing tools like Molecular Dynamic (MD) simulations and plane wave DFT (PW-DFT) calculations, unusual electro-mechanical coupling between different crystallographic axes is demonstrated, highlighting the role of inherent anisotropy that is present in the organic single crystals which translates in an anisotropy of their electro-mechanical coupling.(III) Protonation-dependent conformation of polyelectrolyte and its role in governing the conductivity of polymeric conducting complexes. Polymeric bis(sulfonyl)imide substituted polystyrenes are currently employed as counter-ions and dopants for conducting poly(3,4-ethylenedioxythiophene) (PEDOT), resulting in PEDOT-polyelectrolyte conducting complexes. Employing MD simulations and DFT calculations, inherent characteristics of the polyelectrolyte like its acid-base behavior, protonation state and conformation, are analyzed in conjunction with available experimental data and the role of these characteristics in modulating the conductivity of resulting PEDOT-polyelectrolyte conducting complexes is highlighted.The above studies, performed on different organic electronic systems, emphasize the importance of inherent characteristics of organic materials in governing the charge transport behavior in these materials. By considering the inherent characteristics of organic electronic materials and systematically incorporating them into simulation models, accuracy of simulation predictions can be greatly improved, thereby serving not only as a tool to design new, stable and high performance organic materials but also for optimizing device performances.

Simulations Monte Carlo

Transport de charge

Désordre énergétique

Réponse électro-mécanique

Constante d'acidité

Polyanions

Monte Carlo simulations

Charge transport

Energetic fluctuations

Electro-Mechanical response

Acidity constant

Polyanions

Estudo das propriedades elétricas de células eletroquímicas emissoras de luz de derivados de polifluoreno / Electric properties study of polymer light-emitting electrochemical cells based on polyfluorene derivatives

Giovani Gozzi

30 November 2011

Células eletroquímicas poliméricas emissoras de luz, PLECs, são dispositivos eletrônicos orgânicos que vêm despertando muito interesse comercial por operarem sob baixa tensão com alto desempenho e sem a necessidade de eletrodos específicos, como o óxido de estanho e índio (ITO), cálcio entre outros. Esta característica confere a possibilidade de processamento de baixo custo e de obter dispositivos flexíveis. Nas PLECs a injeção de portadores eletrônicos de carga nas interfaces, entre a camada ativa do dispositivo e seus eletrodos, é facilitada por ação de espécies iônicas, que são inseridas no material polimérico por adição de um sal. Do ponto de vista científico, o interesse atual reside na completa compreensão dos fenômenos de transporte de portadores eletrônicos no interior do dispositivo. Hoje existem dois modelos concorrentes. Um considera o transporte eletrônico por difusão e o outro leva em consideração a dopagem eletroquímica e a consequente formação de uma junção PIN (semicondutor dopado tipo-p camada isolante semicondutor dopado tipo-n). Nesse contexto, propusemos a fabricação e caracterização elétrica de PLECs com diversas composições e espessuras a fim de confrontar os resultados experimentais com os modelos em questão. Demonstramos a existência de uma concentração crítica de sal, abaixo da qual a operação da PLEC é promovida predominantemente por injeção auxiliada pela formação de duplas-camadas devido ao movimento iônico. No regime de tensões mais elevadas, além da injeção, ocorre a dopagem tipo-p e tipo-n e a formação da junção PIN. Além disso, determinamos que para tensões superiores à de operação o dispositivo apresenta comportamento ôhmico, com resistência elétrica proporcional à espessura do dispositivo e praticamente independente da temperatura. Nossos resultados mostraram que no regime de tensões mais baixas deve ocorrer um processo de transporte por difusão, mas à medida que a tensão aumenta, inicia-se um processo de dopagem tipo-p de um lado e tipo-n de outro, aumentando a condutividade das regiões dopadas e finalizando com a formação de uma junção PIN. Mostramos também que a tensão acumulada nas duplas-camadas independe do tipo de polímero eletrônico, e que a tensão de operação, aquela na qual o polímero luminesce, é semelhante á do gap da banda proibida do polímero luminescente. / Polymer light emitting electrochemical cells, PLECs, are organic electronic devices that have attracted commercial interest because they operate at low voltage and exhibit high performance without the need of specific electrodes such as indium tin oxide (ITO), calcium and others. This feature provides low cost of fabrication and exible devices. The charge injection in the PLECs is facilitated by the action of ionic species, which are inserted in the polymeric material by adding a salt. This thesis treats with a controversy related to transport phenomena along the bulk of the device. Currently, there is two opposite models. One that considers that transport is driven by diffusion mechanism; and the other takes into account the formation of a PIN junction (p-type semiconductor insulating layer n-type semiconductor). Here, we proposed the fabrication and characterization of PLECs having different compositions and thickness, and the results were faced up to the models. We showed the existence of critical concentration of salt, below of which the operation of the PLECs are mainly due to injection stimulated by the ionic double-layer. For higher applied voltages, the injection still exists but it is followed by a PIN junction formation. We also verified that for voltages above the turn-on the device electrical resistance is proportional to the sample thickness and is practically temperature-independent. Our results showed that for low voltages the transport is dominated by diffusion, but as the voltage increases, the semiconducting layer starts to be doped: p-type in one side, and n-type in the other. Therefore, the conductivity of the semiconducting layer increases, and it finalizes by the formation of the PIN junction. Finally, we showed that the double-layer characteristic does not depend on the electronic polymer, and that the value of the turn-on voltage is very close to that of the electronic gap of the forbidden band.

Célula eletroquímica emissora de luz

Dispositivos emissores de luz

Eletrônica orgânica

Fenômenos de transporte de cargas

Charge transport phenomena

Light-emitting device

Light-emitting electrochemical cell

Organic electronics

Estudo de propriedades elétricas de filmes poliméricos sob irradiação eletrônica / Electrical properties of polymeric films under low-energy electron beam irradiation

Lucas Fugikawa Santos

29 April 1998

A técnica de injeção de cargas por feixe eletrônico em materiais poliméricos pode ser utilizada como uma importante ferramenta no estudo das propriedades elétricas destes materiais. Fenômenos tais como a emissão eletrônica secundária, o transporte e armazenamento de portadores de carga no volume do material, fenômenos de injeção e condutividade induzida por radiação podem ser observados em películas finas de dielétricos lançando mão desta poderosa técnica. Neste trabalho, utilizamos um canhão de elétrons de energia variável (O a 10 keV) na irradiação de amostras de polianilinas, por nós sintetizadas, para o estudo da emissão secundária e de transporte no volume. Alguns experimentos foram também realizados com o poli(fluoreto de vinilideno), que é um polímero bem mais resistivo que as polianilinas. As medidas de emissão eletrônica foram feitas em circuito aberto, enquanto as medidas de transporte foram obtidas em circuito fechado. Neste segundo tipo de configuração, procuramos fazer uma análise do comportamento da corrente através da amostra pela observação de transientes rápidos (da ordem de 10 ms) de corrente gerados pela injeção de pacotes de carga de penetração bem definida a partir da superfície bombardeada. Propriedades elétricas intrínsecas como a condutividade do material e a permissividade elétrica, e extrínsecas como a condutividade na região irradiada foram utilizadas como parâmetros no ajuste dos resultados experimentais. / Charge injection in polymeric materials by electron beam is a powerful technique in the study of electrical properties of such materials. Secondary emission, transport and storage phenomena, as well as radiation-induced conductivity are among the subjects related to dielectrics that can be investigated. At present work we used an electron beam system (O to 10 keV) to irradiate polyaniline films, synthesized in our laboratory, and to perform studies of secondary emission and transport phenomena. Some experiments were also carried out with poly(viny1idene fluoride), a more resistivity polymer. Secondary emission measurements were carried out in an open-circuit configuration while the transport ones used a short circuit mode. Fast transient phenomena (about 10 ms) were also studied in details. Intrinsic electric properties, such as conductivity and dielectric constant, and extrinsic ones, like the induced conductivity in the irradiated region of the sample, were obtained in the fitting between the model and the experimental results.

Armazenamento de carga

Eletretos

Feixe de elétrons

Irradiação eletrônica

Polímeros

Porpriedades elétricas

Transporte de carga

Charge storage

Charge transport

Electrets

Electrical properties

Electron beam

Eletronic irradiation

Polymers