Global ETD Search

81	Ultrafast energy conversion processes in photosensitive proteins and organic nanostructures for photovoltaic applications / Processus de conversion d'énergie ultra-rapide dans des protéines photosensibles et nanostructures organiques à visée photovoltaïque Cheminal, Alexandre 17 April 2015 (has links) Les techniques de spectroscopie femtoseconde permettent d’étudier les processus de conversion d’énergie dans les système organiques. Elles permettent d’étudier les populations photo-générées et leur évolution à l’échelle de ces photoréactions. Elles permettent de comprendre les transferts d’énergie et de charge intra- et inter-moléculaires à l’origine du fonctionnement de ces systèmes.La protéine de rétinal Anabaena sensroy Rhodopsin est un photocommutateur naturel, qui est étudié afin de comprendre les paramètres à l’origine de l’efficacité quantique d’isomérisation. Nous avons pu déterminer cette efficacité quantique pour les deux formes stables du rétinal ainsi que leur dynamique d’isomérisation dans les mêmes conditions expérimentales.La génération de charge dans des couches actives pour le photovoltaique organique est étudiée dans un système composé d’un mélange de PCBM et d’un donneur organique dérivé du colorant BODIPY. L’influence de la nanostructuration de la couche active sur la génération de charge est étudiée. La génération de charge est limitée dans ce système par la recombinaison des charges générées et par la diffusion des excition aux interfaces donneur-accepteur. Ces observations indiquent que l’amélioration de la nanostructuration de la couche active peut permettre d’augmenter les rendements de photo-génération de charge. / Femtosecond transient spectroscopies are used to investigate photonic energy conversion inorganic systems. These techniques allow to observe the ground and excited states of themolecules at the timescale of the photoreactions. It is used to understand the inter- andintramolecular energy and charge transfers leading to the desired photochemical process.The natural photoswiching retinal protein Anabaena sensory Rhodopsin is studied to understand the key parameters ruling the isomerisation quantum yield. We could determine the isomerisation quantum yield of both stable forms and their dynamics in the very same experimental conditions.Charge generation is investigated in small molecule bulk heterojunction active layers for organic solar cells made of PCBM and a BODIPY dye-derivative donor. The influence of the active layer morphology on charge generation is studied. The charge generation is limited by charge recombination but also by exciton diffusion to the donor-acceptor interface. The active layer morphology has to be improved to achieve more efficient organic solar cells with these materials. Photochimie Transfert de charge Photovoltaique organique Spectroscopie ultrarapide Protéine de rétinal Isomérisation Optique non linéaire Photonique Photochemistry Charge transfer Organic photovoltaics Ultrafast spectroscopy Retinal proteins Isomerization Nonlinear optics 537.6 541.3 572.6
82	Příprava a charakterizace tenkých vrstev nízkomolekulárních materiálů pro organickou fotoniku / Deposition and characterization of low molecular thin films for organic photonics Omasta, Lukáš January 2013 (has links) This diploma thesis is focused on characterization of properties of new organic materials with respect to its potential application in organic photonics. The theoretical part contains a themed literature research on low molecular thin films for organic photonics, mainly phthalocyanines together with description and structure of the photovoltaic energy conversion. The practical part includes the preparation of thin layers of selected organic materials for organic photonics. Prepared thin films were characterized by optical methods and current voltage characteristics. Based on these results, the thin films and structure of solar cells were optimalized. Acquired data were used to determine the materials and structures suitable for photonics applications.
83	Interfacial and Solvent Processing Control of Phenyl-C61-Butyric Acid Methyl Ester (PCBM) Incorporated Polymer Thin Films Huq, Abul Fatha Md. Anisul 27 May 2015 (has links) No description available. Polymers Plastics P3HT PCBM Polymer Organic Photovoltaics Engineering Solvent Mixed Solvent In-Situ GIWAXS, Solvent Annealing Soft Confinement Thermal Annealing GIWAXS GISAXS Organic Electronics XPS AFM Dark Field Microscopy
84	Light, Matter, Action: Electronic Relaxation Processes in Biomolecular Photosensitizers and in Photovoltaics DiScipio, Regina 31 May 2018 (has links) No description available. Physical Chemistry Chemistry Analytical Chemistry
85	Ultrafast electronic processes at nanoscale organic-inorganic semiconductor interfaces Parkinson, Patrick January 2009 (has links) This thesis is concerned with the influence of nanoscale boundaries and interfaces upon the electronic processes that occur within both organic and inorganic semiconductors. Photoluminescent polymers, highly conducting polymers and nanoscale inorganic semiconductors have been investigated using state-of-the-art ultrafast optical techniques, to provide information on the sub-picosecond photoexcitation dynamics in these systems. The influence of dimensionality on the excitation transfer dynamics in a conjugated polymer blend is studied. Using time-resolved photoluminescence spectroscopy, the transfer transients both for a three-dimensional blend film, and for quasi-two-dimensional monolayers formed through intercalation of the polymer blend between the crystal planes of a SnS2 matrix have been measured. A comparison of the experimental data with a simple, dimensionality-dependent model is presented, based on point dipole electronic coupling between electronic transition moments. Within this approximation, the energy transfer dynamics are found to adopt a three-dimensional character in the solid film, and a two-dimensional nature in the monolayers present in the SnS2 -polymer nanocomposite. The time-resolved conductivity of isolated GaAs nanowires has been investigated by optical-pump terahertz-probe time-domain spectroscopy. The electronic response exhibits a pronounced surface plasmon mode that forms within 300 fs, before decaying within 10 ps as a result of charge trapping at the nanowire surface. The mobility has been extracted using the Drude model for a plasmon and is found to be remarkably high, being roughly one third of that typical for bulk GaAs at room-temperature and indicating the high quality and low bulk defect density in the nanowires studied. Finally, the time-resolved conductivity dynamics of photoexcited polymer-fullerene bulk heterojunction blends for two model polymers, P3HT and MDMO-PPV, blended with PCBM are presented. The observed terahertz-frequency conductivity is characteristic of dispersive charge transport for photoexcitation both at the π−π* absorption peak (560 nm for P3HT), and significantly below it (800 nm). The photoconductivity at 800 nm is unexpectedly high, which is attributed to the presence of a charge transfer complex. In addition, the excitation-fluence dependence of the photoconductivity is studied over more than four orders of magnitude. The time-averaged photoconductivity of the P3HT:PCBM blend is over 20 times larger than that of P3HT, indicating that long-lived positive polarons are responsible for the high photovoltaic efficiency of polymer:fullerene blends. At early times (~ ps) the linear dependence of photoconductivity upon fluence indicates that interfacial charge transfer dominates as an exciton decay pathway, generating charges with mobility of at least ~0.1cm2 V−1 s−1. At later times, a sub-linear relationship shows that carrier-carrier recombination effects influence the conductivity on a longer timescale (> 1 μs). 537.622
86	Material and device design for organic photovoltaics Howells, Calvyn T. January 2015 (has links) This thesis presents novel materials for photovoltaic conversion. The materials described are solution-processable organic semiconductors and have been used in the fabrication of organic photovoltaic cells (OPVs). The widely used PEDOT:PSS layer was investigated in P3HT and PTB7 photovoltaics. By doping, the efficiencies recorded were amongst the highest reported in the field using a conventional architecture. Two low band-gap BODIPY-based polymers were introduced and shown to have properties favourable for optoelectronics. Photovoltaics consisting solely of the polymers as the active component surpassed the performance expected without the use of an acceptor, indicating ambipolar behaviour, which was verified by charge carrier mobility measurements. When blended with an acceptor, the devices demonstrated a short-circuit current density similar to that of P3HT, a well-studied and successful OPV material. They also revealed a broad spectral response and were shown to operate as photodiodes. Two small molecules containing diketopyrrolopyrrole (DPP) and BODIPY were introduced and characterised. The addition of thiophenes red shifted the absorption but did not result in a sufficient bathochromic shift. Instead, a propensity to aggregate limited the performance. PLQY measurements showed the aggregation to quench luminescence. The study demonstrated the importance of controlling aggregation for efficient devices. Two solution-processable small molecules with a germanium-bridged spiro centre were investigated, and the molecular, electrochemical and optical properties discussed. The small molecule with shorter conjugation length exhibited an interesting packing motif shown to be favourable for charge transport. The mobility measurements were an order of magnitude higher than those reported for sexithiophene, a small molecule analogue, and the same order of magnitude as P3HT. The two-dimensional charge transporting nature of the material was verified with two independent techniques: time of flight (TOF) and organic field-effect transistor (OFET) measurements. The mobility of the material was found to vary with annealing, a result of morphological changes. These were studied with optical, electron and scanning probe microscopies. By controlling the morphology with the implementation of a well-defined annealing method, it was possible to improve the performance of OFETs and planar-heterojunction OPVs. Solution-processed bulk-heterojunction OPVs were fabricated, characterised and optimised with Ge spiro molecules. A PCE similar to that of P3HT, 2.66 %, was achieved for the one, whilst a PCE of 1.60 % was obtained for the other. The results are encouraging, and there is scope for improvement by increasing the overlap between the absorption and solar spectrum, for example. 621.31
87	Synthesis of Conjugated Polymers and Adhesive Properties of Thin Films in OPV Devices / Synthèse de Copolymères Conjugués et Mesure de l’Adhésion des Films Minces dans les Cellules Solaires Organiques Gregori, Alberto 12 November 2015 (has links) La production d’énergie avec des cellules photovoltaïques organiques (OPV) est une des applications les plus prometteuses des semi-conducteurs organiques, en raison de leur compatibilité avec les substrats flexibles permettant des produits légers, peu chers et décoratifs. Pendant longtemps, poly(3-hexylthiophène) (P3HT) a été le polymère de choix dans l’OPV combiné au [6,6]-phényl-C61-butanoate de méthyle (PC61BM) comme accepteur. Toutefois, des recherches récentes ont porté sur des polymères avec meilleures absorption et processabilité, qui peuvent assurer des rendements et des durées de vie plus élevés. Des rendements de conversion en puissance (PCE) au-dessus de 11% ont récemment été démontrés. Cette thèse rapporte sur la synthèse et la caractérisation de deux séries de polymères dits à faible bande interdite, LBGs "push-pull" (ou donneur-accepteur), constitués de l'unité donneuse 4,4-bis(2-ethylhexyl)-5,5'-dithieno[3,2-b:2',3'-d]silole (DTS) combinée au 3,6-dithiophén-2-yl-2,5-dihydro-pyrrolo[3,4-c]pyrrole-1,4-dione (DPP) ou au 5,7-di(thiényl)thiéno[3,4-b]pyrazines (DTP), comme unité acceptrice. Toutes les molécules et les polymères ont été caractérisés chimiquement et leur propriétés optoelectroniques, morphologiques et photovoltaïques ont été determinées. La série DTS-DPP a été choisie parce qu'elle est représentative d'un grand nombre de polymères LBG et a fourni un modèle facilement accessible pour évaluer l'importance de la chaîne latérale utilisée sur leur propriétés optoélectroniques et thermiques. Les premières études sur les dispositifs à base de DTS-DPP:PC61BM ont été menées, pour déterminer les propriétés photovoltaïques. Le meilleur dispositif permet d’obtenir un PCE de 1,7% avec JSC de 5,9 mA cm-2, VOC de 0,54 V et FF de 0,58. La série DTS-DTP a été choisie pour la stabilité chimique élevée des deux unités et pour la facilité de substitution des groupes latéraux. La polymérisation a partiellement abouti, en donnant seulement des oligomères. La caractérisation chimique a pu être effectuée, mais leur application dans l’OPV n'a pas été explorée. En termes de stabilité, les mécanismes de défaillance électrique des dispositifs OPV ont été étudiés, montrant une méconnaissance de leur stabilité mécanique. Les contraintes caractéristiques de chaque couche mince présentes dans les cellules solaires organiques constituent la force motrice à l’origine de la délamination des interfaces faibles ou même leur decohésion, causant une perte de l'intégrité et des performances du dispositif. Une technique pour sonder les couches ou les interfaces fragiles dans les cellules solaires polymère:fullerene est présentée. Elle a été développée par l'établissement d'un nouveau set-up pour le test pull-off, développé en utilisant un dispositif à géométrie inverse, de structure verre/ITO/ZnO/P3HT:PC61BM/PEDOT:PSS/Ag. Les dispositifs délaminés ont montré que le point le plus faible est localisé à l'interface AL/HTL, en bon accord avec la littérature. La technique a été étendue en variant les deux couches sensibles, en utilisant differents polymères LBG pour l’AL (PSBTBT et PDTSTzTz) en combinaison avec deux formulations de PEDOT:PSS, CleviosTM HTL Solar à base d'eau et un nouveau HTL Solar 2 à base de solvant organique. Une différence entre la contrainte à la rupture des dispositifs avec différentes combinaisons de AL et HTL est visible, suggérant différents chemins de fracture, tel que confirmé par la caractérisation de surface et qui pourrait être corrélée avec la différence de comportement de la couche active avec les deux formulations de PEDOT:PSS. Une autre voie adoptée, a été d’introduire une couche d’interface de copolymère à blocs amphiphile afin d'améliorer la compatibilité des deux couches. Cette stratégie n'a pas abouti et la nouvelle architecture présente une adhésion réduite. La poursuite de l’amélioration des procédés de fabrication de ces dispositifs pourrait faire de cette nouvelle architecture, une alternative viable. / Organic photovoltaic (OPV) devices are one of the most promising applications of organic semiconductors due to their compatibility with flexible plastic substrates resulting in light weight, inexpensive and decorative products. For a long time poly(3-hexylthiophene) (P3HT) has been the polymer of choice in OPV devices in combination with [6,6]-phenyl-C61-butyric acid methylester (PC61BM) as acceptor. However, recent research has focused on polymers with improved absorbance and processability that can ensure higher efficiencies and longer lifetimes (Low BandGap polymers (LBGs)). This has been fully demonstrated with a power conversion efficiency (PCE) above 11%. This thesis reports synthesis and characterization of two series of so-called “push-pull” (or donor-acceptor) LBGs based on the donor unit 4,4′-bis(2-ethylhexyl)-5,5’-dithieno[3,2-b:2′,3′-d]silole (DTS) and either 3,6-dithiophen-2-yl-2, 5-dihydropyrrolo[3,4-c]pyrrole-1,4-dione (DPP) or 5,7-di(thienyl)thieno[3,4-b]pyrazines (DTP), as acceptor unit. All π-conjugated molecules and polymers were characterized by chemical investigation and their optoelectronic, morphological, and photovoltaic properties are reported. The DTS-DPP series was chosen because representative of a large number of LBG polymers and provided an easily accessible and useful template to discover the importance of the type of side-chain used on the polymer optoelectronic and thermal properties. First studies on DTS-DPP:PC61BM devices have been conducted, in order to investigate any effect on their photovoltaic properties. The best device obtained had a PCE of 1.7% with JSC of 5.9 mA•cm-2, VOC of 0.54 V and FF of 0.58. The DTS-DTP series was chosen for the high stability of the two units and for the ease of substitution of the side-groups. The synthesis was partially successful and only oligomers were obtained. Nonetheless, chemical characterization was performed but their application in OPV was not explored. In terms of device stability, the electrical failure mechanisms in OPV devices have been investigated, while little is known about their mechanical stability. The characteristic thin film stresses of each layer present in organic solar cells, in combination with other possible fabrication, handling and operational stresses, provide the mechanical driving force for delamination of weak interfaces or even their de-cohesion, leading to a loss of device integrity and performance. A technique to probe weak layers or interfaces in inverted polymer:fullerene solar cells is presented. It was developed by establishing a new set-up for the pull-off test. The technique was developed using inverted device, with the structure glass/ITO/ZnO/P3HT:PC61BM/PEDOT:PSS/Ag. The delaminated devices showed that the weakest point was localized at the active layer/hole transporting layer interface, in good agreement with the literature. The technique was extended varying both sensitive layers, using different p-type low bandgap (co)polymers for the active layer (PSBTBT and PDTSTzTz) in combination with two different PEDOT:PSS formulations, the water based CleviosTM HTL Solar and a new organic solvent based HTL Solar 2. The half-devices produced upon destructive testing have been characterized by contact angle measurement, AFM and XPS to locate the fracture point. A difference in the stress at break for devices made with different combinations of active and hole transporting layers is visible, suggesting different fracture paths, as confirmed by surface characterization and could be correlated to the different behavior of the active layer with the two PEDOT:PSS formulations. Another solution adopted, it had been the introduction of amphiphilic block-copolymer interlayer to enhance the compatibility of the two layers. This strategy was not successful and the new architecture showed reduced adhesion strength. Further development of device processing could make this new architecture a viable alternative. Polymères conjugués Faible bande interdite Photovoltaïque organique Adhésion Couches minces Cellules solaires OPV Test d'adhérence par traction, Intégrité mécanique Conjugated polymers Low bandgap Organic photovoltaics Adhesion Thin films OPV devices Pull-off test Mechanical integrity
88	Study of Organic Semiconductors for Device Applications Stella, Marco 12 March 2010 (has links) Organic semiconductors are being investigated as an alternative to more traditional materials such as silicon, for the fabrication of different types of electronic devices. The advantages of such materials are flexibility, lightness and quick and low cost device production methods. In this thesis we analyze some small molecule organic semiconductors for their use in devices such as thin film transistors and photovoltaic cells. These materials, deposited in thin films on glass by thermal vacuum evaporation, are copper phthalocyanine (CuPc) and pentacene, p-type materials, fullerene (C60), PTCDA and PTCDI-C13, that are n-type. We analyze their optical properties by optical transmittance measurement and photothermal deflection spectroscopy (PDS). By such means we obtain the absorption coefficient of the materials in sub-gap region (near infrared - NIR), directly related with the density of electronic states. Furthermore, we examine thin film microstructure by X-ray diffraction (XRD) in order to observe if it is amorphous or polycrystalline. The data obtained by optical methods are used to calculate optical gap (Eg) and Urbach energy (Eu). The former of these parameters gives important information about the absorption properties of the material in the visible and NIR ranges of the spectrum, while the latter about the structural disorder in the film. Since a clear model for organic semiconductors is still not defined, in both cases we employ models that are usually considered in the case of inorganic semiconductors. The XRD analysis indicates that, in the deposition conditions used in this work, only C60 grows with amorphous structure while all the other materials are polycrystalline. Such result is used to determine which law can be used to estimate the optical gap: the general law for direct allowed electronic transitions in semiconductors for polycrystalline materials or the Tauc law for amorphous ones. The Urbach law, usually employed to have an idea about the amount of disorder in amorphous films, is used for all our materials as an indicator of thin film quality. Furthermore, we examine the stability of the materials over time under exposure to direct radiation and atmosphere and to compare the results with the ones obtained for samples simply exposed to atmosphere. PTCDA and CuPc have demonstrated to be stable against oxidizing agents that are present in atmosphere while the other materials suffer modifications in their optical properties. Such variations, principally located in the sub-gap region of the absorption region, indicate that an increase in the absorption level is obtained, probably due to the presence of defects that could work as charge carrier traps. Annealing treatments are performed on the degraded materials to observe that the degradation process is not reversible. Organic photovoltaic cells always include a heterojunction between two semiconductors, so the same study is performed on mixtures of two materials, a p-type and an n-type one, testing all the possible combinations between the investigated materials. The films are obtained by co-evaporating the two materials in 1:1 proportion. A mixture containing a degrading material also degrades. Heat treatments performed on the samples yield a partial crystallization of some materials but not of others and fail to recover the original optical properties when degradation occurs. Finally, two types of devices are fabricated: thin film transistors (TFTs) using PTCDI-C13 and diodes with CuPc. In the first case we obtain very interesting results, determining that the devices work as typical n-type channel transistors. An analysis of the device characterizations allows us to determine the density of electronic states in the channel obtaining a result that is very similar to the one obtained by optical means on the same material. In the second case we observe the typical diode behaviour but the response with light of such devices, characterized by having a structure similar to the one of Schottky type solar cells, is very low. / Los semiconductores orgánicos están siendo investigados como alternativos a materiales más tradicionales, como el silicio, para la fabricación de varios tipos de dispositivos electrónicos. Las ventajas que presentan tales materiales son flexibilidad, ligereza, rapidez y bajo coste de los métodos de producción de los dispositivos orgánicos. En esta tesis se analizan algunos semiconductores orgánicos de molécula pequeña para su aplicación en dispositivos como los transistores en capa delgada y las células fotovoltaicas. Tales materiales, depositados en capa delgada por evaporación térmica en vacío, son ftalocianina de cobre (CuPc) y pentaceno, de tipo p, fullereno (C60), PTCDA y PTCDI-C13, de tipo n. Se analizan las propiedades ópticas de ellos por medio de la medida de Trasmitancia Óptica y de la Espectroscopia de Deflección Fototérmica (PDS). Además se analiza la microestructura de las capas delgadas por difracción de rayos X (XRD) con el objetivo de observar si las capas tienen estructura amorfa o policristalina. Los datos son utilizados para calcular el gap óptico (Eg) y la energía de Urbach (Eu). Se analiza la estabilidad de los materiales con el pasar del tiempo y la exposición a irradiación directa, por un lado, y a la atmosfera, por otro lado. El fullereno es el único material que se deposita con estructura amorfa. Además se ha observado que CuPc y PTCDA son estables frente a la degradación por exposición a agentes oxidantes. Las células fotovoltaicas orgánicas incluyen siempre una heterounión entre dos semiconductores, así que se repite el mismo estudio sobre mezclas de dos materiales, uno de tipo p y otro de tipo n, probando todas las combinaciones posibles con los materiales analizados. Se observa que en una mezcla que incluya un material que presenta inestabilidad también hay degradación. Los tratamientos térmicos efectuados sobre las muestras han permiten obtener una parcial cristalización de algunos materiales pero no de otros y no llevan a recuperar las propiedades ópticas originarias, perdidas con la degradación. Finalmente, se fabrican dos tipos de dispositivos: TFTs de PTCDI-C13 y diodos de CuPc. En el primer caso se obtienen resultados interesantes, detectando que los dispositivos funcionan como típicos transistores en capa delgada de tipo n. En el segundo caso se observa el típico comportamiento de los diodos. Sin embargo, la respuesta con luz de tales dispositivos, de estructura análoga a fotocélulas de tipo Schottky, es muy escasa. Organic Photovoltaics Optical Properties Organic Semiconductors Phototermal Deflection Spectroscopy PDS Optical Absorption Propietats òptiques Propiedades ópticas Semiconductors orgànics Semiconductores orgánicos Absorció òptica Absorción óptica Ciències Experimentals i Matemàtiques 53
89	Films minces nanostructurés de domaines sub-10 nm à partir de copolymères biosourcés pour des applications dans le photovoltaïque organique / Sub-10 nm nano-structured carbohydrate-based block copolymer thin films for organic photovoltaic applications Otsuka, Yoko 04 January 2017 (has links) La structuration nanométrique par l'auto-assemblage des copolymères à blocs est l'une des stratégies « bottom-up » prometteuses pour contrôler la morphologie de la couche active de cellules photovoltaïques organiques. Dans cette thèse, une nouvelle classe de copolymère constitué d’un bloc semi-conducteur π-conjugué poly(3-hexylthiophène) (P3HT) regioregulier et d’un bloc oligosaccharidique a été synthétisée et a montré une auto-organisation en nanostructures périodiques de domaine inférieure à 10 nm. Deux systèmes de copolymères à blocs ont été synthétisés, le P3HT-bloc-maltoheptaose peracétylé (P3HT-b-AcMal7) et le P3HT-bloc-maltoheptaose (P3HT-b-Mal7), via une réaction de chimie "clic" entre les segments oligosaccharidiques et P3HT fonctionnalisés en extrémité. Une étude exhaustive sur leur comportement d'auto-assemblage par des analyses AFM, TEM et de diffusion des rayons X a révélé que le copolymère à bloc P3HT-b-AcMal7 montre une propension à s'auto-assembler par recuit thermique en structures lamellaires avec une résolution inférieure à 10 nm, c’est-à-dire la morphologie et la taille idéale pour la couche active d’une cellule photovoltaïque organique. De plus, ce système présente l’une des plus petites tailles de domaines réalisées par l'auto-assemblage de copolymères à blocs à base de P3HT. Un réseau lamellaire composé uniquement du P3HT a été obtenu par gravure chimique sélective du bloc sacrificiel AcMal7 à partir d'un film nano-organisé de P3HT-b-AcMal7 et ceci sans affecter la structure lamellaire initiale. Les domaines vides du AcMal7 gravé pourront être remplis par un composé accepteur d'électrons tel que le [6,6]-phényl-C61-butanoate de méthyle (PCBM) pour l’application photovoltaïque comme perspective de cette thèse. Les résultats et les connaissances acquises dans cette étude devraient permettre d'augmenter les performances des prochaines générations de cellules photovoltaïques organiques. / Nanoscale patterning through self-assembly of block copolymers is one of the promising bottom-up strategies for controlling active layer morphology in organic photovoltaics. In this thesis, a new class of carbohydrate-based semiconducting block copolymers consisting of π-conjugated regioregular poly(3-hexylthiophene) (P3HT) and oligosaccharides were synthesized and self-organized into sub-10 nm scale periodic nanostructures. Two different diblock copolymers, i.e. P3HT-block-peracetylated maltoheptaose (P3HT-b-AcMal7) and P3HT-block-maltoheptaose (P3HT-b-Mal7) were synthesized via "click" reaction between end-functionalized oligosaccharide and P3HT moieties. A comprehensive investigation of their self-assembly behavior by AFM, TEM, and X-ray scattering analyses revealed that the P3HT-b-AcMal7 diblock copolymer has the ability to self-assemble into sub-10 nm scale lamellar structure, which is the ideal morphology of the active layer in organic photovoltaics and one of the smallest domain sizes achieved by self-assembly of P3HT-based block copolymers, via thermal annealing. Nano-patterned film made of P3HT was attained by selective chemical etching of AcMal7 block from microphase-separated P3HT-b-AcMal7 template without affecting the original lamellar structure. The resultant void where the etched-out AcMal7 block existed will be filled with electron acceptor compounds such as [6,6]-phenyl-C61-butyric acid methyl ester (PCBM) for photovoltaic application as a perspective of this thesis. The results and knowledge obtained in this study are expected to provide further advances and innovation in organic photovoltaics. Copolymères biosourcés Polymères pi-Conjugués Oligosaccharides Photovoltaïque organique Carbohydrate-Based block copolymers Pi-Conjugated polymers Oligosaccharides Sub-10 nm scale self-Assembly Organic photovoltaics 540
90	Systèmes modèles donneur accepteur pour le photovoltaïque organique étudiés par microscopie à sonde locale / Model Donor-Acceptor Systems for Organic Photovoltaics Investigated by Scanning Probe Microscopy Fuchs, Franz 25 September 2014 (has links) Pour cette thèse, des systèmes donneur-accepteur (DA) modèles pour le photovoltaïque organique ont été étudiés par microscopie à force atomique en mode non contact (nc-AFM) et microscopie à sonde de Kelvin (KPFM). Ces systèmes DA présentent une structure et des propriétés électroniques mieux contrôlées que dans la plupart des hétérojonctions DA en volume.Afin, d'étudier les propriétés optoélectroniques d'architectures DA présentant une séparation de phase à l'échelle de la dizaine de nanomètres, il est indispensable d'optimiser la résolution des modes nc-AFM/KPFM. Dans ce travail, l'influence du régime d'interaction pointe-surface sur les mesures a été étudiée dans le cas d'auto-assemblages de P3DDT sur substrat HOPG. Nous avons ainsi démontré que l'imagerie dans le régime d'interaction à courte portée améliore non seulement la résolution latérale, mais permet également de réaliser des mesures de hauteur plus réalistes.Ensuite, un système DA à base de FG1:[70]PCBM a été étudié. Pour ce mélange DA, la nanostructure et l'échelle de la séparation de phase peuvent être ajustées grâce aux propriétés cristal liquide du composé donneur FG1. Les potentiels mesurés dans le noir sont consistants avec la morphologie attendue en surface et en volume. La relation entre le photo-potentiel de surface (SPV) et le régime d'interaction pointe-surface a pu être précisément analysée. Une résolution optimale est obtenue dans les images de SPV en travaillant près du seuil de dissipation.Enfin, une nouvelle génération de diades comprenant des groupements donneur et accepteur a été étudiée. La nature de l'auto-assemblage sur HOPG a été établie sur la base d'études comparatives de microscopie à effet tunnel et de nc-AFM, avec le support de simulations en mécanique et dynamique moléculaire. Les mesures de photo-potentiel de surface ont ensuite permis de démontrer qu'il était possible d'étudier les mécanismes de photo-génération des porteurs jusqu'à l'échelle de la mono-couche moléculaire. / During this thesis, model donor-acceptor (DA) systems for organic photovoltaics have been studied by non-contact atomic force microscopy (nc-AFM) and Kelvin probe force microscopy (KPFM). To enhance the understanding of the optoelectronic processes on the nanoscale, DA systems with better defined structural and electronic properties than the one of most bulk heterojunction blends (BHJ), have been studied.With DA phase-separations of below 10nm in organic photovoltaic systems, the highest possible resolution has to be achieved by KPFM to investigate optoelectronic processes. It has been shown that nc-AFM/KPFM measurements in the regime of short range (SR) forces can increase imaging resolution. In preparation of such investigations, the influence of the interaction regime on the topographic measurement via KPFM has been studied for a self-assembly of P3DDT on HOPG. It is demonstrated that imaging in the SR-regime not only increases the lateral resolution, but also assures a correct topographic height values.In a next step, DA blends of FG1:[70]PCMB have been studied by KPFM. For these BHJs, the structure and the scale of the DA phase-separation can be tuned via the liquid crystal behavior of the donor FG1. The in dark potential contrasts are consistent with surface and bulk morphology. The relationship between the surface photovoltage (SPV) and the tip-sample interaction regime has been analyzed. An optimal resolution for SPV imaging is obtained when measuring next to the onset of dissipation.Finally, a new generation of DA dyad with donor and acceptor moieties has been studied. Its self-assembly on HOPG has been determined via a comparative study by scanning tunneling microscopy and nc-AFM plus molecular mechanics and dynamics simulations. By KPFM the charge carrier generation and collection has been analyzed down to the level of a single molecular layer. A clear relationship between the dyads' molecular assembly and their photovoltaic properties can be established. AFM non contact Microscopie à Sonde de Kelvin Matériaux Pi-Conjugués Interfaces Donneur-Accepteur Microscopie à Effet Tunnel Photovoltaïque Organique Non-contact AFM Kelvin Probe Force Microscopy Pi-Conjugated Materials Donor-Acceptor Interfaces Scanning Tunneling Microscopy Organic Photovoltaics 530

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