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1	Optimization of material composition and processing parameters for hybrid organic-inorganic solar cells Salpeter, Garrett Morgan 16 February 2011 (has links) The widespread adoption of hybrid organic-inorganic solar cells has been delayed by low performance. Improving performance requires a firm understanding of how to optimize both material composition and processing parameters. In this thesis, we examine processing parameters that include solution composition, annealing temperature, and the rates of spin casting and evaporative coating. We also find that the optimal weight ratio for the active layer of a ZnO:P3HT solar cell is 40 wt. % ZnO. / text Hybrid solar cell Organic photovoltaics Zinc oxide nanoparticles Poly(3-hexylthiophene) Solar cells
2	Hybridsolarzellen aus ZnO-Nanostrukturen und konjugierten Polymeren Käbisch, Sven 17 June 2015 (has links) Hybridsolarzellen werden sowohl aus ZnO-Schichten als auch ZnO-Nanostrukturen und Poly[2,6-(4,4-bis-(2-ethylhexyl)-4H-cyclopenta[2,1-b;3,4-b'']dithiophen)-alt-4,7(2,1,3-benzothiadiazol)] (PCPDTBT) hergestellt. Das Wachstum der ZnO-Schichten und Nanostrukturen wird mittels gepulster Laserdeposition (PLD) auf Saphirsubstraten durchgeführt. Die Schichten weisen eine c-Achsenorientierung auf. Die Polarität einer ZnO-Schicht bestimmt die Morphologie der nachfolgend gewachsenen ZnO-Nanostrukturen. Dabei kann die Morphologie kontrolliert zwischen Nanostäbchen auf einer O-terminierten ZnO-Schicht und Nanowänden auf einer Zn-terminierten ZnO-Schicht eingestellt werden. Untersuchungen mittels konvergenter Elektronenbeugung zeigen, dass die Nanostrukturen immer Zn-terminiert sind. Die Grenzfläche zwischen ZnO und PCPDTBT wird mit Photoelektronenspektroskopie untersucht und ergibt eine Vakuumniveauangleichung zwischen beiden Materialien. Prinzipiell ist der Übergang für photovoltaische Aktivität geeignet, jedoch sind die erzielten Wirkungsgrade sehr niedrig. Die Ursache ist eine niedrige Exzitonendissoziationseffizienz, die durch die Benutzung von sol-gel ZnO, kleinen organischen Molekülen und einer niedrigeren Leitfähigkeit vom PLD-ZnO verbessert werden kann. Dennoch beträgt der maximale Wirkungsgrad der Hybridsolarzellen nur 0,21 %. / Hybrid solar cells are built from ZnO layers and ZnO nanostructures and Poly[2,6-(4,4-bis-(2-ethylhexyl)-4H-cyclopenta[2,1-b;3,4-b'']dithiophene)-alt-4,7(2,1,3-benzothiadiazole)] (PCPDTBT). The growth of the ZnO layers and nanostructures is performed with pulsed laser deposition (PLD) on sapphire substrates. The samples exhibit a c-axis orientation. The polarity of a ZnO layer determines the morphology of subsequently grown ZnO nanostructures. One can control the morphology between ZnO nanorods on an O-terminated layer and nanowalls on a Zn-terminated layer. Studies with convergent electron beam diffraction reveals that the ZnO nanostructures are always Zn-terminated. The interface between ZnO and PCPDTBT is studied with photoelectron spectroscopy and shows a vacuum level alignment between both materials. In principle, the interface is suitable for photovoltaic activity, however, the achieved power conversion efficiencies are very low. This is due to a low exciton dissociation efficiency, which can be improved by the use of sol-gel ZnO, small organic molecules, and a lower conductivity of the PLD ZnO. Nevertheless, the maximum power conversion efficiency amounts to 0.21 %, only. Hybridsolarzelle ZnO-Nanostrukturen konjugierte Polymere gepulste Laserdeposition hybrid solar cell ZnO nanostructures conjugated polymers pulsed laser deposition 530 Physik 29 Physik, Astronomie ZN 5160 ZP 3730 ddc:530
3	Synthèse de nanocristaux de type Chalcopyrite en vue d'applications en cellules solaires / Organic/inorganic hybrid thin films for multijunction solar cells Lefrançois, Aurélie 28 October 2013 (has links) Cette thèse porte sur l’étude de nanocristaux semi-conducteurs ternaires, et leur application dansdes cellules solaires hybrides organiques/inorganiques. Les nanocristaux semi-conducteurs absorbentla lumière à des longueurs d’ondes déterminées par leur taille et leur composition, et conduisent lescharges électriques. Ils sont stables en solution, ce qui permet un dépôt de couches minces à bascout. Aujourd’hui les meilleurs rendements en cellules solaires hybrides sont obtenus à partir de nanocristauxbinaires contenant soit du plomb, soit du cadmium. Les nanocristaux ternaires conserventles propriétés particulières des nanocristaux binaires tout en permettant de s’affranchir des élémentstoxiques. Cependant, leur synthèse reste à optimiser pour contrôler de leur structure cristalline et leurcomposition.Nous avons réalisé, par voie chimique, la synthèse de nanocristaux de CuInS2 de taille et de compositioncontrôlées. En suivant in situ la synthèse de ces nanocristaux par diffraction des rayons X sous rayonnementsynchrotron nous avons trouvé que les précurseurs s’organisent avant nucléation sous forme deplans espacés par deux longueurs du ligand utilisé (ici dodécanethiol, DDT). Cela impacte nucléationet croissance des nanocristaux. Les ligands stabilisent les nanocristaux en solution colloïdale, maisleur caractère isolant peut inhiber le transfert et le transport de charges. Le remplacement du ligandd’origine (DDT) par un ligand plus court, l’éthylhexanethiol (EHT), modifie les niveaux d’énergie etpermet d’augmenter la conductivité des films de nanocristaux. Nous avons intégré des nanocristauxde CuInS2 entourés d’EHT dans des cellules hybrides constituées d’un polymère conjugué (P3HT) etd’un fullerène (PCBM). L’efficacité des cellules solaires contenant des nanocristaux entourés d’EHTest significativement améliorée par rapport à celle des cellules de P3HT :PCBM réalisées dans lesmêmes conditions. Le transfert et la mobilité des charges sont étudiés par RPE sous éclairement etphoto-CELIV respectivement. De ces études il ressort que l’amélioration des cellules provient d’unemeilleure génération et dissociation des charges. / This work is devoted to the study of ternary semiconductor nanocrystals, and their application inhybrid organic/inorganic solar cells. Semiconductor nanocrystals absorb light at controlled wavelength(depending on their size and composition) and are able to transport charges. They form a colloidalsolution in organic solvent compatible with low-cost deposition in thin films. Nowadays, the bestefficiency for such hybrid solar cells is obtained with binary nanocrystals containing lead or cadmium.Ternary nanocrystals preserve the opticla and electronic properties of binary nanocrystals withoutrelying on toxic elements, but it is still a challenge to control their composition and structure.In this thesis, CuInS2 nanocrystals of controlled size and composition were syntesized. A study ofnucleation and growth was carried out by following the synthesis in situ with X-ray radiation at thesynchrotron. This has shown that precursors’ organize themselves into plans of atoms separated by twotimes the length of the ligand (here dodecanethiol, DDT). Ligands stabilize the nanocrystals in colloidalsolution, but their insulating character inhibits efficient charge transfer and transport. Ligand exchangewith ethylhexanethiol (EHT) improves the conductivity of thin films and changethe energetic level ofthe nanocrystals.We studied an approach of hybrid solar cell design, consisting in a bulk heterojunctionof two semiconductor organic components (P3HT and PCBM) and CuInS2 nanocrystals. The efficencyof the cells where nanocrystals are added are better than the one with only P3HT:PCBM. The chargetransfer and mobility was studied by the mean of light induced ESR and CELIV respectively. It hasshown that the improvement of the solar cell efficiency is mainly related to an improvement of thecharge generation and dissociation in the ternary blend. Nanocristaux semi-conducteurs CuInS2 Cellules solaires hybrides Fonctionnalisation de surface Ligands Semiconductor nanocrystals CuInS2 Hybrid solar cell Ligand exchange Differential pulse voltammetry (DPV)
4	Polymer intercalation of chemically bath deposited iron sulphide and nickel sulphide thin films Molete, Puleng Alina January 2017 (has links) M. Tech. (Department of Chemistry, Faculty of Applied and Computer Sciences), Vaal University of Technology. / In chemical bath deposition (CBD) method, deposition of metal chalcogenide semiconducting thin films occurs due to substrate maintained in contact with a dilute chemical bath containing metal and chalcogenide ions. Semiconducting nickel sulphide (NiS) and iron sulphide (FeS) thin films have been prepared on a glass substrate by varying the deposition parameters such as the concentration of solutions, deposition time, temperature and pH. Multi-layered thin films were deposited on glass substrate and the spin-cast conductive polymer, poly (3.4-ethylenedioxythiopene) polystyrene sulfonate (PEDOT: PSS) was intercalated. The characterization of the films was carried out using UV-Vis spectroscopy, scanning electron microscopy (SEM) coupled with energy-dispersive X-ray spectroscopy (EDX), atomic force microscopy (AFM) and X-ray diffraction (XRD). Single layer nickel sulphide was deposited at room temperature, pH 10 and the deposition period of 3 hours, triethanolamine was used as the complexing agent. Iron sulphide was deposited for 6 hours at 70 °C with the pH of 2.5 using EDTA as a complexing agent. Generally the iron and nickel sulphide were prepared from their respective nickel or iron salt and the thiourea or thiosulfate as a source of sulphide ions in solution. SEM and AFM results show that the FeS film is evenly coated and has uniform grain size with the roughness of ~22.4 nm and thickness of ~23.8 nm. The optical absorption analysis of FeS showed the band gap energy of ~2.9 eV which blue shifted from the bulk. The EDX analysis confirms the compositions of iron and sulphur in FeS films. XRD pattern showed amorphous films for both FeS and NiS thin films due to the amorphous nature of the glass substrate. The optical data of NiS film were analysed and exhibited the band gap energy of ~3.5 eV and ~3.3 eV for successive ionic layer adsorption and reaction (SILAR), which is the modified CBD, both blue shifted from the bulk. The films were observed to have thickness value of ~35.7 nm and ~2.3 nm SILAR with the roughness of ~112.5 nm and ~35.4 nm SILAR from AFM results. SEM confirmed the uniformly distributed film presented by AFM analysis. The chemical composition of Ni and S were confirmed by EDX spectra. The PEDOT: PSS was intercalated between the FeS as the first layer and NiS as the top layer which gave the thickness of ~18.7 nm and roughness of ~115.2 nm from AFM analysis. PEDOT: PSS acted as a passive layer that protects and stabilize the FeS layer and NiS as the third active layer which enhanced the optical absorption of the film when using SILAR method for solar application. Polymer Nickel sulphide Chemically bath deposited (CBD) Iron sulphide thin films Nickel sulphide thin films Inorganic thin film deposition Organic thin film deposition Solar cell Hybrid solar cell Organic/polymer solar cell Dissertations, Academic -- South Africa. Nanostructured materials. Thin films. Semiconductors -- Materials. Solar cells.

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