Global ETD Search

441	Low energy photovoltaic conversion in MIND structures / Conversion photovoltaïque en basse énergie dans les structures MIND Basta, Marek 05 September 2013 (has links) Dispositifs photovoltaïques d'aujourd'hui convertissent l'énergie solaire en électricité de manière propre, renouvelable et inépuisable et représentent un remplacement possible pour les combustibles fossiles. Toutefois, afin de rivaliser avec les sources d'énergie classiques une augmentation significative de l'efficacité de conversion est inévitable. Dans ce travail, nous nous concentrons sur des aspects pouvant propulser le rendement de conversion au-dessus des limites de cellules présentes. La première partie de l'étude est consacrée à de nouvelles idées théoriques considérés comme le photovoltaïque de 3ème génération, alors que le plus d'intérêt est maintenu à étudier les avantages possibles de la multiplication d'électrons faible seuil. Dans la deuxième partie de l'étude, nous développons un modèle qui permet un traitement précis des propriétés optiques et de transport des structures de silicium avec des interfaces enterrées. Les analyses théoriques et expérimentales approfondies des structures existantes MIND sont ensuite effectuées. En étudiant le flux exacte et la distribution d'énergie à l'intérieur de plusieurs structures dans le cadre de leur géométrie, nous estimons les rendements quantiques possibles et les comparer avec les résultats expérimentaux. Grâce aux moyens de simulations numériques couplées avec caractérisation expérimentale, nous extrayons l'efficacité de la collecte de porteur de cellules étudiées. De nouveaux effets sont observés, une telle augmentation possible de l'efficacité de la collecte au-dessus de l'unité. Une analyse plus approfondie des résultats expérimentaux couplés avec l'étude numérique suit quelques explications classiques et non classiques de l'augmentation de l'efficacité de la collecte ou l'augmentation résultante de l'efficacité quantique. Avec la plupart des explications classiques exclu, nous concluons que l'explication la plus probable, mais non définitive de cet effet peut être interprété comme le résultat d'une multiplication des porteurs faible seuil. / Photovoltaic devices of today convert solar energy into electricity in a clean, renewable and inexhaustible way and represent a possible replacement for the fossil fuels. However, in order to compete with classical energy sources a significant increase in the conversion efficiency is inevitable. In this work, we concentrate on the aspects able to raise the conversion efficiency above the limitations of present cells. The first part of the study is devoted to new theoretical ideas considered as 3rd generation photovoltaics, while the most interest is kept at studying the possible benefits of electron multiplication at low-energies. In the second part of the study, we develop a model that allows a precise treatment of optical and transport properties of silicon structures with buried interfaces. Extensive theoretical and experimental analyses of existing MIND structures are then conducted. By studying the exact flux and power distribution inside several structures in conjunction with their geometry, we estimate the possible quantum efficiencies and compare them with experimental results. Through the means of numerical simulations coupled with experimental characterization, we extract the carrier collection efficiency of studied cells. New effects are being observed, such a possible increase in collection efficiency above unity. A deeper analysis of the experimental results coupled with the numerical study analyzes several classical and non-classical explanations of the increase in collection efficiency or the resulting increase in the quantum efficiency. With most of the classical explanations ruled out, we conclude that the most probable, but not definitiveexplanation of this effect can be interpreted as the result of a low-energy carrier multiplication. Cellules solaires Électron faible seuil Photovoltaïque Silicium 3e génération Solar cell Electron multiplication High efficiency Silicon 3rd generation 621.38 537.62
442	Sputtering-based processes for thin film chalcogenide solar cells on steel substrates Bras, Patrice January 2017 (has links) Thin film chalcogenide solar cells are promising photovoltaic technologies. Cu(In,Ga)Se2 (CIGS)-based devices are already produced at industrial scale and record laboratory efficiency surpasses 22 %. Cu2ZnSn(S,Se)4 (CZTS) is an alternative material that is based on earth-abundant elements. CZTS device efficiency above 12 % has been obtained, indicating a high potential for improvement. In this thesis, in-line vacuum, sputtering-based processes for the fabrication of complete thin film chalcogenide solar cells on stainless steel substrates are studied. CIGS absorbers are deposited in a one-step high-temperature process using compound targets. CZTS precursors are first deposited by room temperature sputtering and absorbers are then formed by high temperature crystallization in a controlled atmosphere. In both cases, strategies for absorber layer improvement are identified and implemented. The impact of CZTS annealing temperature is studied and it is observed that the absorber grain size increases with annealing temperature up to 550 °C. While performance also improves from 420 to 510 °C, a drop in all solar cell parameters is observed for higher temperature. This loss is caused by blisters forming in the absorber during annealing. Blister formation is found to originate from gas entrapment during precursor sputtering. Increase in substrate temperature or sputtering pressure leads to drastic reduction of gas entrapment and hence alleviate blister formation resulting in improved solar cell parameters, including efficiency. An investigation of bandgap grading in industrial CIGS devices is conducted through one-dimensional simulations and experimental verification. It is found that a single gradient in the conduction band edge extending throughout the absorber combined with a steeper back-grading leads to improved solar cell performance, mainly due to charge carrier collection enhancement. The uniformity of both CIGS and CZTS 6-inch solar cells is assessed. For CZTS, the device uniformity is mainly limited by the in-line annealing process. Uneven heat and gas distribution resulting from natural convection phenomenon leads to significant lateral variation in material properties and device performance. CIGS solar cell uniformity is studied through laterally-resolved material and device characterization combined with SPICE network modeling. The absorber material is found to be laterally homogeneous. Moderate variations observed at the device level are discussed in the context of large area sample characterization. Power conversion efficiency values above 15 % for 225 cm2 CIGS cells and up to 5.1 % for 1 cm2 CZTS solar cells are obtained. CIGS CZTS solar cell photovoltaics thin film sputtering annealing gallium grading blister uniformity stainless steel Engineering and Technology Teknik och teknologier
443	Investigation of the Performance of a Large PV system Solanes Bosch, Júlia January 2017 (has links) One of the main social challenges that society is facing nowadays is the energy crisis. So, head towards renewable energy resources such as solar, hydraulic, wind, geothermal and biomass, could be the best solution. Solar photovoltaic is one of the most promising sources to produce electricity due to its cleanness, noiselessness and sustainability, and the fact that it is inexhaustible. However, the power output of the PV systems varies notably because of the ambient conditions: temperature and solar radiation. The main aim of this thesis is to study if the PV system installed on the wall of the new football arena Gavlehov in Gävle is providing the amount of power promised before the installation. To achieve reliable results, the first step is to develop and install a monitoring system for recording the real power of the system and the ambient conditions at the same time. After that, an evaluation of the performance of the system during one week will be done, comparing the theoretical power and the real power obtained. The theoretical power will be calculated in two ways: using the data from a pyranometer and on the other hand, from a reference solar cell. This will permit to compare which one matches better with the reality. Different factors such as the temperature, the irradiance and the angle of incidence are studied to know the real influence that they have on the performance of a PV installation. The results obtained show that the measurement system installed is reliable and that the model used to evaluate the system is correct. It can be concluded that using a reference solar cell to calculate the theoretical power of the system is easier to align and it has the same angular behaviour as a PV module than employing a pyranometer. Regarding the installation, all the panels work similarly and the system works at nominal power. So, it provides the amount of power promised before the installation. Key words: Renewable energy, PV system, solar radiation, nominal power, pyranometer, solar cell. Renewable energy PV system solar energy pyranometer solar cell Elektroteknik och elektronik Energy Systems Energisystem
444	Materials and Device Engineering for Efficient and Stable Polymer Solar Cells Hansson, Rickard January 2017 (has links) Polymer solar cells form a promising technology for converting sunlight into electricity, and have reached record efficiencies over 10% and lifetimes of several years. The performance of polymer solar cells depends strongly on the distribution of electron donor and acceptor materials in the active layer. To achieve longer lifetimes, degradation processes in the materials have to be understood. In this thesis, a set of complementary spectroscopy and microscopy techniques, among which soft X-ray techniques have been used to determine the morphology of polymer:fullerene based active layers. We have found that the morphology of TQ1:PC70BM films is strongly influenced by the processing solvent and the use of solvent additives. We have also found, by using soft X-ray techniques, that not only the light-absorbing polymer TQ1, but also the fullerene is susceptible to photo-degradation in air. Moreover, the fullerene degradation is accelerated in the presence of the polymer. Additionally, this thesis addresses the role of the interfacial layers for device performance and stability. The commonly used hole transport material PEDOT:PSS has the advantage of being solution processable at room temperature, but this layer is also known to contribute to the device degradation. We have found that low-temperature processed NiOx is a promising alternative to PEDOT:PSS, leading to improved device performance. Even for encapsulated polymer solar cells, some photo-induced degradation of the electrical performance is observed and is found to depend on the nature of the hole transport material. We found a better initial stability for solar cells with MoO3 hole transport layers than with PEDOT:PSS. In the pursuit of understanding the initial decrease in electrical performance of PEDOT:PSS-based devices, simulations were performed, from which a number of degradation sources could be excluded. / With the increasing global demand for energy, solar cells provide a clean method for converting the abundant sunlight to electricity. Polymer solar cells can be made from a large variety of light-harvesting and electrically conducting molecules and are inexpensive to produce. They have additional advantages, like their mechanical flexibility and low weight, which opens opportunities for novel applications. In order for polymer solar cells to be more competitive, however, both the power conversion efficiencies and lifetimes need to further improve. One way to achieve this is to optimize the morphology of the active layer. The active layer of a polymer solar cell consists of electron donating and electron accepting molecules whose distribution in the bulk of the film is a major factor that determines the solar cell performance. This thesis presents the use of complementary spectroscopy and microscopy methods to probe the local composition in the active layer of polymer solar cells. The stability of the active layer is studied and the interplay between the photo-degradation of the donor and acceptor molecules is investigated. Additionally, this thesis addresses how the interfacial layers between the active layer and the electrodes can influence device performance and stability. / <p>I publikationen felaktigt ISBN 978-91-7063-739-1</p> polymer solar cell photovoltaics morphology photo-degradation conjugated polymer fullerene synchroton-based techniques hole transport layers Physical Sciences Fysik
445	Integration of High Efficiency Solar Cells on Carriers for Concentrating System Applications Chow, Simon Ka Ming January 2011 (has links) High efficiency multi-junction (MJ) solar cells were packaged onto receiver systems. The efficiency change of concentrator cells under continuous high intensity illumination was done. Also, assessment of the receiver design on the overall performance of a Fresnel-type concentration system was investigated. We present on receiver designs including simulation results of their three-dimensional thermal operation and experimental results of tested packaged receivers to understand their efficiency in real world operation. Thermal measurements from solar simulators were obtained and used to calibrate the model in simulations. The best tested efficiency of 36.5% is obtained on a sample A receiver under 260 suns concentration by the XT-30 solar simulator and the corresponding cell operating temperature is ~30.5°C. The optimum copper thickness of a 5 cm by 5 cm simulated alumina receiver design was determined to be 6 mm and the corresponding cell temperature under 1000 suns concentration is ~36°C during operation. Multi-junction Solar Cell Solar Concentrator Solar Receiver Receiver Thermal Management XT-30 High Power Solar Concentrator
446	Development of Field Scenario Ray Tracing Software for the Analysis of Bifacial Photovoltaic Solar Panel Performance Li, Chu Tu January 2016 (has links) This thesis is based on a project "Bifacial Photovoltaic Energy Production Analysis" to build a detailed simulation model system accurately simulate bifacial panel performance under real field radiation conditions and deployment configuration, and to predict its corresponding energy yield. To the author’s up-to-date knowledge, the model system is unpreceded among same type simulation software in complexity, details in consideration, ranges of deployment and parameters. The model system can also be used as a platform for more components and variables to be added on, such as adding on more rows of panel arrays to simulate bifacial solar farm scenario; and adding spectral information for more accurate analysis. The system components’ sub-models were carefully chosen based on a broad literature review in related aspects; especially in sky diffuse radiance, ground reflection, and bifacial solar cells. Built in MATLAB© based on mathematical expressions from above said models, the system consists of 5 bifacial panels and their racking as shading objects and the central panel performance is under investigation and has taken consideration of all possible panel azimuth and elevation combinations. Model simplification and resolution are carefully considered so to achieve a good balance in complexity, computation load and output accuracy. Output reliability is confirmed with other people’s work. Furthermore, the model has been fully checked and peer tested. Outputs under different parameter settings are analysed and discussed. Conclusions and recommended future work are provided at the end of the thesis. Bifacial solar cell Bifacial solar panel Perez sky diffuse model Gueymard directional reflection solar panel simulation Solar panel shading
447	Desenvolvimento de células fotovoltaicas orgânicas e flexíveis / Development of flexible photovoltaic organic solar cells Matsumoto, Agatha, 1987- 22 August 2018 (has links) Orientadores: Rubens Maciel Filho, Fernando Ely / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Química / Made available in DSpace on 2018-08-22T07:45:29Z (GMT). No. of bitstreams: 1 Matsumoto_Agatha_M.pdf: 4679251 bytes, checksum: 08fb9e84038f307956ec356550160f03 (MD5) Previous issue date: 2013 / Resumo: Células fotovoltaicas orgânicas (OPVs) tem sido foco de intensa pesquisa devido ao seu potencial de baixo custo de produção e pela típica característica de serem flexíveis. Apesar de tais vantagens, estes dispositivos ainda têm baixa eficiência quântica (PCE). Este trabalho explora o desenvolvimento de processos de fabricação reprodutíveis e o uso de novos materiais em estruturas de dispositivo fotovoltaico. Inicialmente foi construído dispositivo padrão seguindo a estrutura de ITO/ PEDOT VpAl/ P3HT:PCBM/ Al, que corresponde à estrutura OPV mais estudada, até hoje, e que conduz a altas eficiências de fotoconversão. Foram ajustados todos os parâmetros físico-químicos para se obter as soluções mais estáveis possíveis e camadas funcionais uniformes do dispositivo padrão. Diversas modificações, neste dispositivo padrão, foram introduzidas para incrementar a eficiência quântica originalmente obtida. Primeiramente, foi testada a aplicação de PEDOT condutor e nanoparticulas (NP) de ZnO como camada buffer em substituição ao PEDOT VpAl. Posteriormente, o composto liquido-cristalino TAPCu-52 foi introduzido como material do tipo-P na camada ativa, em substituição ao polímero P3HT. Cristais líquidos também foram estudados como aditivos funcionais na camada ativa para aumentar a mobilidade dos portadores de carga e facilitar a separação do par elétron-buraco fotogerado. Por fim, buscando tornar o dispositivo completamente flexível foi realizada a substituição do eletrodo transparente de ITO por uma camada de PEDOT condutor, obtida pelo método de spray manual e ultrasônico. As caracterizações elétricas e morfológicas das células OPV, mostraram que todas as modificações feitas levaram a resultados positivos em relação ao dispositivo padrão fabricados / Abstract: Organic photovoltaics (OPVs) have been the focus of research due its flexible characteristics and low cost of production. Despite such advantages these devices still have low quantum efficiency (PCE), which is an obstacle for commercialization. This work explores reliable fabrication processes and new materials for OPV structures. For comparison, we fabricated standard devices having the well studied structure ITO/ PEDOT VpAl/ P3HT:PCBM/ Al which can lead to high fotoconversion efficiencies. Physical and chemical parameters were modified to achieve stable solutions and uniform functional layers. Several modifications in this standard device were introduced in order to increase the original PCE obtained. Firstly, conductive PEDOT and ZnO nanoparticles layers were added in replacement of the PEDOT VpAl as buffer. Afterwards, the liquid-crystalline compound TAPCu-52 was studied as p-type material in the active layer to substitute the P3HT polymer. Liquid crystals were also investigated as functional additives to increase the charge carrier mobility and electron-hole separation. Finally, ITO was changed by a conductive PEDOT layer deposited by handheld and ultrasonic spray as transparent anode in order to have a more flexible device. In general, the electrical and morphological characterizations indicated that all studied modifications had positive effect on the PCE of the manufactured OPV devices / Mestrado / Desenvolvimento de Processos Químicos / Mestra em Engenharia Química Células solares Geração de energia fotovoltaica Polímeros condutores Condutores orgânicos Solar cell, Photovoltaic power generation Conducting polymers Organic conductors
448	Desenvolvimento de um novo eletrólito polimérico baseado num derivado de PEO e metais de transição para aplicação em dispositivos fotoeletroquímicos / Development of new polymer electrolyte based on a PEO derivative and transition metals for photoelectrochemical devices application Santos Júnior, Garbas Anacleto, 1988- 24 August 2018 (has links) Orientador: Ana Flávia Nogueira / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-24T11:57:50Z (GMT). No. of bitstreams: 1 SantosJunior_GarbasAnacleto_M.pdf: 5163839 bytes, checksum: 6d357533b5e3fc16413a4febf8f9d075 (MD5) Previous issue date: 2014 / Resumo: Neste trabalho são apresentados os resultados da preparação e caracterização de eletrólitos poliméricos usando matriz polimérica de um copolímero derivado de PEO - poli (óxido de etileno-co-2-(2-metoxietoxi) etil glicidil éter) - P(EO-EM) - visando à substituição do par redox, I/I3 , usualmente mais comum em células solares do tipo DSSC, por pares de íons de metais de transição, como Fe e Co . Os eletrólitos foram preparados utilizando razões mássicas fixas de P(EO-EM):GBL de 30-70%. Para os eletrólitos de ferro foram utilizados os sais de FeCl2 + FeCl3·6H2O e para os eletrólitos de cobalto CoCl2 · 6H2O + CoF3. Em ambos os casos foram estudados razões molares entre os cátions de valência II:III de 1:1 e 10:1. Diferentes razões mássicas foram estudadas, sendo estas de 2, 5, 8 e 16% para os eletrólitos de ferro e de 1, 2, 3 e 5% para os eletrólitos de cobalto. Valores máximos de condutividade para os eletrólitos contendo sais de ferro foram de 1,88 x 10 e 1,40 x 10 S cm-1, para concentrações de 16% de sal e razões de 1:1 e 10:1 (Fe:Fe), respectivamente. Enquanto que no caso dos eletrólitos contendo cátions de cobalto foram de 1,41 x 10 e 1,16 x 10 S cm, para concentrações de 5% de sal e razões de 1:1 e 10:1 (Co:Co), respectivamente. Testes de PIA- Photoinduced Absorption Spectroscopy mostraram a eficiência do par redox Fe para regeneração dos corantes L0, N719, D35 e Z907. Entretanto, os mesmos testes mostraram a eficiência do par redox Co para regeneração somente do corante L0. A confecção de dispositivos do tipo DSSC com eletrólitos contendo sais de Fe e Co apresentaram resultados insatisfatórios, possivelmente relacionado com a alta taxa de recombinação do elétron ejetado no TiO2 com os mediadores redox / Abstract: This work presents the results of the preparation and characterization of polymer electrolytes using polymeric matrix of a PEO copolymer-poly (ethylene oxide-co-2-(2-methoxyethoxy) ethyl glycidyl ether) - P (EO-EM) - in order to substitute the redox couple , I-/I3-, usually most common mediators in DSSC solar cells, by transition metal ions pairs, such as Fe and Co . The electrolytes were prepared using fixed P(EO-EM) : GBL weight ratios of 30-70 % . The iron electrolytes were prepared using FeCl2 + FeCl3 o 6H2O salts and CoCl2 o 6H2O + CoF3 were used for the cobalt electrolytes. In both cases, it was studied the molar ratios between cations with valence of II: III of 1:1 to 10:1. Different weight ratios were studied, 2 , 5, 8 and 16% for iron electrolytes and 1 , 2, 3 and 5% for the cobalt electrolytes . Maximum conductivity values for the electrolyte containing iron salts were 1.88 x 10 and 1.40 x 10 S cm at salts concentrations of 16 % and ratios from 1:1 to 10:1 (Fe:Fe), respectively. While in the case of electrolyte containing cobalt cations the conductivity values were 1.41 x 10 and 1.16 x 10 S cm -1 at salts concentrations of 5 % and ratios from 1:1 to 10:1 ( Co:Co), respectively . PIA tests - Photoinduced Absorption Spectroscopy- showed the efficiency of the FeII/III redox couple for the regeneration of L0 , N719 , Z907 and D35 dyes. However, the same tests have shown that the CoI redox couple were only able to regenerate the L0 dye. The DSSC devices with electrolytes containing Fe and Co salts showed unsatisfactory results, possibly related to the high rate of recombination of the electron ejected in TiO2 with the redox mediators / Mestrado / Quimica Inorganica / Mestre em Química Celula solar de TiO2/corante Eletrólito polimérico Condutividade ionica Dye sensitized TiO2 solar cell Polymer electrolyte Ionic conductivity
449	Charakterizace materiálů pro perovskitové solární články impedančními metodami / Impedance spectroscopy characterization of perovskite solar cell materials Křečková, Jitka January 2020 (has links) The Master‘s thesis deals with the topic of perovskite solar cells with the main focus on the materials used for the active layer. In the introductory part, the electrical and optical properties of halide perovskites are described and specific examples of perovskite crystals are introduced. The description of impedance and photoimpedance measurement methods used for characterization of perovskite solar cells is also included in the thesis. The measurement of electrochemical impedance spectroscopy was conducted on four perovskite crystals and equivalent circuit was formed to fit the obtained data. Parameters of the circuit elements were acquired using the fitting method and were further evaluated in experimental part of this thesis.
450	Příprava perovskitových solárních článků se standardní n-i-p strukturou a jejich optimalizace / Preparation of perovskite solar cells with regular n-i-p architecture and their optimization Poláková, Simona January 2021 (has links) The diploma thesis deals with the study of perovskite solar cells with a regular n-i-p architecture. The theoretical part of this work is mainly focused on the stability of perovskite solar cells, i.e. thermal stability and the influence of UV radiation on final perovskite solar cell stability. Furthermore, the deposition methods, the architecture of solar cells and the materials used for the preparation of electron and hole transport layers were described in more detail. The experimental part deals with the optimization of the preparation of perovskite solar cells (especially in terms of resulting photovoltaic conversion efficiency), with a description of the structure preparation process of the final photovoltaic cell and the interpretation of the measured results.

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