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Electron microscopy studies of hybrid perovskite solar cellsCacovich, Stefania January 2018 (has links)
Over the last five years hybrid organic-inorganic metal halide perovskites have attracted strong interest in the solar cell community as a result of their high power conversion efficiency and the solid opportunity to realise a low-cost as well as industry-scalable technology. Nevertheless, several aspects of this novel class of materials still need to be explored and the level of our understanding is rapidly and constantly evolving, from month to month. This dissertation reports investigations of perovskite solar cells with a particular focus on their local chemical composition. The analytical characterisation of such devices is very challenging due to the intrinsic instability of the organic component in the nanostructured compounds building up the cell. STEM-EDX (Scanning Transmission Electron Microscopy - Energy Dispersive X-ray spectroscopy) was employed to resolve at the nanoscale the morphology and the elemental composition of the devices. Firstly, a powerful procedure, involving FIB (Focus Ion Beam) sample preparation, the acquisition of STEM-EDX maps and the application of cutting edge post-processing data techniques based on multivariate analysis was developed and tested. The application of this method has drastically improved the quality of the signal that can be extracted from perovskite thin films before the onset of beam-induced transformations. Morphology, composition and interfaces in devices deposited by using different methodologies and external conditions were then explored in detail by combining multiple complementary advanced characterisation tools. The observed variations in the nanostructure of the cells were related to different photovoltaic performance, providing instructive indications for the synthesis and fabrication routes of the devices. Finally, the main degradation processes that affect perovskite solar cells were probed. STEM-EDX was used in conjunction with the application of in situ heating, leading to the direct observation of elemental species migration within the device, reported here for the first time with nanometric spatial resolution. Further analyses, involving a set of experiments aimed to study the effects of air exposure and light soaking on the cells, were designed and performed, providing evidence of the main pathways leading to the drastic drop in the device performance.
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Exploring nanoscale properties of organic solar cellsMönch, Tobias 19 November 2015 (has links)
The demand for electrical energy is steadily increasing. Highly efficient organic solar cells based on mixed, strongly absorbing organic molecules convert sunlight into electricity and, thus, have the potential to contribute to the worlds energy production. The continuous development of new materials during the last decades lead to a swift increase of power conversion efficiencies (PCE) of organic solar cells, recently reaching 12%.
Despite these breakthroughs, the usage of highly complex organic molecules blended together to form a self-organised absorber layer results in complicated morphologies that are poorly understood. However, the morphology has a tremendous impact on the photon-to-electron conversion, affecting all processes ranging from light absorption to charge carrier extraction.
This dissertation studies the role of phase-separation of the self-organised thin film blend layers utilized in organic solar cells. On the molecular scale, we manipulate the phase-separation, using different molecule combinations ranging from the well-known ZnPc:C 60 blend layers to highly efficient oligothiophene:C60 blend layers. On the macroscopic scale, we shape the morphology by depositing the aforementioned blend layers on differently heated substrates (in-vacuo substrate temperature, Tsub).
To characterise the manufactured blend layers, we utilize high resolution microscopy techniques such as photoconductive atomic force microscopy, different electron microscopic techniques, X-ray microscopy etc., and various established and newly developed computational simulations to rationalise the experimental findings. This multi-technique, multi-scale approach fulfils the demands of several scientific articles to analyse a wide range of length scales to understand the underlying optoelectronic processes.
Varying the mixing ratio of a ZnPc:C60 blend layer from 2:1 to 6:1 at fixed in vacuo substrate temperature results in a continuous increase of surface roughness, decrease of short-circuit current, and decrease of crystallinity. Additionally performed density functional theory calculations and 3D drift-diffusion simulations explain the observed crystalline ZnPc nanorod formation by the presence of C60 in the bulk volume and the in turn lowered recombination at crystalline ZnPc nanorods. Moving to oligothiophene:C60 blend layers used in highly efficient organic solar cells deposited at elevated substrate temperatures, we find an increase of phase-separation, surface roughness, decrease of oligothiophene-C60 contacts, and reduced disorder upon increasing Tsub from RT (PCE=4.5%) to 80 °C (PCE=6.8%). At Tsub =140 °C, we observe the formation of micrometer-sized aggregates on the surface resulting in inhomogeneous light absorption and charge carrier extraction, which in turn massively lowers the power conversion efficiency to 1.9%. Subtly changing the molecular structure of the oligothiophene molecule by attaching two additional methyl side chains affects the thin film growth, which is also dependent on the substrate type.
In conclusion, the utilized highly sensitive characterisation methods are suitable to study the impact of the morphology on the device performance of all kinds of organic electronic devices, as we demonstrate for organic blend layers. At the prototypical ZnPc:C60 blend, we discovered a way to grow ZnPc nanorods from the blend layer. These nanorods are highly crystalline and facilitate a lowered charge carrier recombination which is highly desirable in organic solar cells.
The obtained results at oligothiophene: C60 blends clearly demonstrate the universality of the multi-technique approach for an in-depth understanding of the fragile interplay between phase-separation and phase-connectivity in efficient organic solar cells. Overall, we can conclude that both molecular structure and external processing parameters affect the morphology in manifold ways and, thus, need to be considered already at the synthesis of new materials.
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Effets d'un vieillissement longue durée sur deux alliages d'aluminium de la série 2000 / Long-term thermal ageing effect on two Al-Cu-(Li) aluminum alloysBello, Nicolas 29 November 2018 (has links)
Ces travaux de thèse réalisés entre l'IRT Saint Exupéry et le CEMES, Université de Toulouse, CNRS ont pour objet l'étude d’alliages de la série 2000 pour des utilisations à des températures intermédiaires, de l'ordre de 200°C. La possibilité d'utiliser ces matériaux à cette température permettrait aux industriels du secteur aéronautique de réduire les coûts de production d'une part, et de diminuer les coûts d'exploitation des aéronefs ainsi plus légers d'autre part. Afin de répondre à cette problématique industrielle, deux nuances commerciales ont été considérées : le 2219-T851 et le 2050-T84. Ces nuances, déjà utilisées dans l'industrie aéronautique, ont été caractérisées à différentes échelles d'observation tout au long d'un vieillissement isotherme à 200°C allant jusqu’à 10000 h. Des observations effectuées à l'aide de divers microscopes optiques et électroniques et couplées à des essais mécaniques macroscopiques ont permis de déterminer l'évolution de ces nuances vieillies dans de telles conditions. Les résultats de cette étude montrent une importante stabilité thermodynamique des précipités nanométriques θ'-Al2Cu. Ces précipités constituent la microstructure fine de la nuance 2219-T851 à réception et apparaissent au cours du vieillissement au sein de la nuance 2050-T84 au détriment des précipités T1-Al2CuLi pourtant à l'origine des meilleures performances mécaniques avant vieillissement. Les évolutions microstructurales sont mises en lien avec les propriétés mécaniques en traction. Ces résultats montrent un intérêt industriel pour la nuance 2219-T851 dont la stabilité des propriétés a été montrée dès 1000h de vieillissement. / The main objective of this work which has been conducted between the IRT Saint Exupéry and the CEMES, Université de Toulouse, CNRS laboratory is to reduce production and exploitation costs of aircraft primary structures by evaluating the potential increase of operating temperatures of aluminum alloys. To do so, two already fit-to-fly Al-Cu alloys have been selected and studied: the 2219-T851 and the 2050-T84. These alloys have been characterized throughout ageing treatments up to 10,000h at 200°C with electronic and optical microscopies in order to evaluate the microstructural changes. Standardized mechanical tests have also been conducted to follow the effects of such ageing on the alloys’ properties. The results have shown the stability of the mechanical properties and the microstructure of the 2219-T851 from 1,000h to 10,000h of ageing. This is attributed to the nano-precipitation of θ'-Al2 Cu, stable during the ageing treatment. Moreover, those precipitates tend to form during the ageing of the 2050-T84 by replacing the well known T1-Al2CuLi phase, unstable during medium range temperature ageing. During this thesis, special attention has been paid on the link between the mechanical properties and the fine scale microstructures of both alloys.
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