Estudo e caracterização de dispositivos fotovoltaicos orgânicos (OPV) baseados em heterojunção de volume / Study and characterization of organic photovoltaic devices (OPV) based on bulk heterojunction

Douglas José Coutinho

26 July 2011

Um dos grandes desafios do século XXI está na produção de energia limpa e renovável, já que a demanda mundial por energia continuará crescendo, assim como a necessidade de despoluir o planeta e de diminuir a emissão dos gases do efeito estufa. Nesse contexto, a conversão de energia solar em elétrica coloca-se como uma excelente alternativa, e com isso a dos dispositivos fotovoltaicos. A tecnologia fotovoltaica baseada no silício e em outros semicondutores orgânicos encontra-se em estágio relativamente avançado, porém o custo de produção e de manutenção a proíbe em uso de grande escala. Mais recentemente, iniciaram-se pesquisas com filmes de semicondutores orgânicos, e a rápida melhora na performance dessas células solares a coloca como promissora ao mercado fotovoltaico. Em nosso trabalho, realizamos estudos sobre a performance de dispositivos fotovoltaicos orgânicos baseados na estrutura de heterojunção, estudando a influência de vários parâmetros na performance dos dispositivos. Usamos como camada ativa para nossos dispositivos o poli(3-hexiltiofeno) (P3HT) regiorregular, que é um polímero condutor de gap eletrônico em torno de 1,8 eV misturado ao [6,6]-fenil-C61-ácido butírico-metil ester (PCBM). Essa mistura é apropriada à dissociação dos éxcitons gerados nas cadeias poliméricas pelos fótons absorvidos porque, sendo o PCBM muito eletronegativo, ele captura o elétron do éxciton antes do processo natural de recombinação. Como esse fenômeno ocorre em todo o volume da camada ativa, o dispositivo leva o nome de heterojunção de volume. A estrutura básica que usamos foi de ITO/P3HT-PCBM/Al, isto é, o ITO como eletrodo transparente e bom injetor de buracos e o alumínio como eletrodo injetor de elétrons. Outros dispositivos foram feitos adicionando uma camada transportadora de buracos entre o ITO e o polímero ativo, o Poli(3,4-etileno dióxido-tiofeno):poliestireno-sulfonado (PEDOT:PSS) e/ou cálcio (Ca) entre a camada de alumínio e o polímero. Verificamos que a performance do dispositivo fotovoltaico é bastante alterada quando mediante o contato utilizado, a espessura da camada ativa e a temperatura em que o tratamento térmico é realizado. Investigou-se também, os mecanismos de injeção, transporte e geração de portadores sob variação de temperatura, no intervalo de 90 à 330K. Foi mostrado que, mediante a variação da temperatura, a corrente de curto circuito (JSC), é governada principalmente pela mobilidade dos portadores. A eficiência dos dispositivos desenvolvidos neste trabalho é comparável aos principais valores obtidos na atualidade. Para obtenção destes resultados, foi necessária intensa pesquisa em processamento, principalmente mantendo todas as etapas de fabricação em atmosfera controlada. / One big challenge of the humanity along the 21st Century is to produce energy based on clean and renewable sources. The energy consumption certainly will increase, as well as the necessity in decreasing the emission of greenhouse gases. In this context, solar energy becomes an important alternative for the production of electric energy, in particular, that of photovoltaic devices. Photovoltaics made of silicon and of other inorganic semiconductors are already available, but due to the high cost is not an alternative to produce energy in a large scale. More recently, the organic photovoltaics, due to their quick progress, have becoming as promising technology for the solar energy market. In this work, we studied bulk heterojunction organic photovoltaics, varying several parameters and its influence on the device performance. We used regio-regular poli(3-hexylthiophene) (P3HT), that has an electronic gap close to 1.8 eV, mixed with [6,6]-phenyl-C61-butyric acid methyl ester (PCBM). PCBM acts in order to dissociate the photogenerated exciton because, being highly electronegative, it captures the electron form the exciton before the recombination process. We used as basic structure the ITO/P3HT-PCBM/Al. ITO as transparent electrode and injector of holes, and aluminum as the electrons injector electrode. In other devices we added a thin layer of Poly(3,4-ethylenedioxythiophene) poly(styrenesulfonate) (PEDOT:PSS), as hole transport layer and/or calcium (Ca) between the Al and the polymer. We verify that the device performance changes considerably with the insertion of such layers, and with the thickness of the active layer and the annealing treatment. We also investigated phenomena related to injection, generation and transport of charge carriers, in the 90-330 K temperature range. We showed that the temperature is the main factor that governs the short-circuit current (JSC). It is important to remark that our devices exhibited similar efficiency compared to that of the literature.

Dispositivos fotovoltaicos orgânicos

Heterojunção de volume

P3HT:PCBM

Bulk heterojunction

Organic photovoltaic devices

P3HT:PCBM

Obtenção por electrospinning e tratamento térmico em ar de sulfeto de cobre, zinco e estanho (CZTS) e sua caracterização microestrutural e de propriedades fotofísicas

Schutz, Priscila

January 2014

O objetivo deste estudo foi a síntese de Cu2ZnSnS4 (CZTS) por electrospinning, sem a etapa de sulfurização e com tratamento térmico em atmosfera ambiente. A solução precursora consistiu na dissolução dos sais dos metais de interesse: tiourea como fonte de enxofre e polivinil butiral (PVB) em etanol como polímero condutor. Esta solução foi submetida ao processo de electrospinning com uma tensão elétrica de 16 kV e uma distância entre coletor e capilar de 120 mm e fluxo de 3 mL/h. O efeito da temperatura de tratamento térmico sobre a formação do CZTS foi investigada. Para isso, o material resultante do processo de electrospinning foi tratado termicamente em diferentes temperaturas: 150°C durante 72h, 150°C durante 24h mais 300°C durante 24h, 300°C durante 48h, 400°C durante 1h, 450°C durante 1h, 500°C durante 1h e 550°C durante 1h. A taxa de aquecimento foi de 0,5°C/mim. A Influência do agente complexante dietanolamina (DEA) sobre as propriedades do material formado, quando adicionado à dolução precursora, foi também investigada. As amostras resultantes destes tratamentos térmicos foram caracterizadas através de análises térmicas (ATG), difração de raios X (DRX), espectroscopia Raman, microscopia eletrônica de varredura (MEV/EDS), microscopia eletrônica de transmissão (MET) e, por medidas ópticas (UV-Vis) e espectroscopia de reflectância difusa (ERD). Foram obtidos filmes homogêneos e compactos com uma espessura de aproximadamente 10 nm. Os resultados indicaram que foi obtida fase CZTS a 400°C, com as razões S/(Cu+Zn+Sn) = 1,1, Cu/(Zn+Sn) = 0,8 e Zn/Sn = 1,26. No entanto, a presença de algumas fases secundárias elevou o band gap para aproximadamente 2,2 eV. Além disso, foi verificado que a adição de DEA na solução precursora não aumenta a qualidade do CZTS formado por electrospinning. / The aim of this work was to study the production of CZTS by electrospinning method without sulfurization process and in-air heat treatment. The precursor solution was prepared by dissolving metal salts, tiourea as a sulfur source and PVB as conductive polymer. The resulting solution was electrospun onto a cylindrical target with an electric voltage of 16 kV at a 120 mm distance and flow rate of 3 mL/h. The effect of in-air heat treatment in the phase formation and morphology of electrospun CZTS fibers were investigated by the following conditions, 150°C for 72h, 150°C for 24h plus 300°C for 24h, 300°C for 48h, 400°C for 1h, 450°C for 1h, 500°C for 1h e 550°C for 1h, with a used a heating rate of 0.5°C.min-1 The Influence of the addition of complexing agent diethanolamine (DEA) on the properties of the final material was investigated. The samples were characterized by thermal analysis (TGA), R-X diffraction, scanning electron microscopy (SEM/EDS), transmission electron microscopy and optical measurements (UV-Vis). The results show the obtainment of a well crystallized CZTS phase with the heat treatment of 400°C with ratios S/(Cu+Zn+Sn) =1.1, Cu/(Zn+Sn) = 0.8 e Zn/Sn = 1.26. Homogeneous and compact films with the morphology of 10 nm spheres were found in this study. However, the presence of some secondary phases increases the band gap to approximately, 2.2 eV. Furthermore, it was found that the addition of DEA in the precursor solution does not increase the quality of CZTS formed by electrospinning.

Células fotovoltaicas

Tratamento térmico

Ensaios de materiais

Eletrofiação

Cu2ZnSnS4

Electrospinning

Photovoltaic devices

Estudo de materiais, estruturas de dispositivos e fenômenos de transporte em sistemas fotovoltaicos híbridos orgânico-inorgânico / Study of materials, device structures and transport phenomena in hybrid photovoltaic systems

Adriana Pereira Ibaldo

26 February 2010

Recentemente tem sido observado grande avanço na área de fotovoltaicos orgânicos e híbridos. Esses dispositivos baseiam-se em diferenças de energia eletrônica nas interfaces dos componentes de uma heterojunção, onde as heterojunções dispersas obtidas via arranjos interpenetrantes com estes dois compostos, em dimensões sub-20-nm, permite coleção efetiva dos portadores de carga fotogerados, mesmo com pequeno comprimento de difusão do éxciton e baixa mobilidade dos portadores de carga. Desta maneira, o estudo e a modificação da interface entre as duas fases é essencial para melhorar a eficiência de conversão desses dispositivos. Este trabalho tem como objetivo investigar heterojunções de dióxido de titânio (TiO2)/poli(3-hexil tiofeno) (P3HT) como camadas ativas em dispositivos fotovoltaicos híbridos. Essas heterojunções são atraentes para fotovoltaicos híbridos por permitir a nanoestruturação do metalóxido antes da incorporação do polímero, levando à obtenção de elevada área interfacial e com a possibilidade de ajustar as propriedades interfaciais mantendo o caráter aceitador/doador desta heterojunção. Os filmes de TiO2 foram obtidos a partir de dispersões coloidais de nanopartículas de anatase, enquanto aqueles de P3HT foram obtidos a partir de sua solução de 1,2-diclorobenzeno. Como eletrodos foram utilizados o óxido de índio dopado com óxido de estanho (ITO) e ouro (Au). A caracterização elétrica e espectroscópica indicou que os parâmetros fotovoltaicos, bem como absorção e fotoluminescência, dependem da submissão dos dispositivos a tratamentos térmicos post-production, evidenciando que o aquecimento induz a mudanças conformacionais no polímero, alterando a interface óxido/polímero. A introdução de grupos carboxilato nas ramificações 3-hexil do P3HT permite melhor contato entre óxido/polímero, sendo favorecido por tratamento térmico. Mais ainda, a infiltração do polímero em filmes de TiO2 nanocristalino levou à obtenção de dispositivos fotovoltaicos de considerável estabilidade, apresentando atividade mesmo após 6 meses após a elaboração destes. Finalmente, neste trabalho também é proposta a utilização de um complexo a base de ftalocianina de zinco como modificador de interface do TiO2, cuja absorção estende a janela espectral do dispositivo até o vermelho e infravermelho próximo. Estudos de fenômenos de transporte, levando-se em conta a fotogeração de portadores e sua recombinação, foram realizados por medidas do espectro de fotocondução no dispositivo / Recently a fast development in organic and hybrid photovoltaic field has been observed. Such devices are fabricated by organic semiconductors within components of a heterojunction, in which bulk heterojunctions obtained via interpenetrating networks at the sub-20-nm length scale. It permits the effective collection of photogenerated charge carriers even with low exciton diffusion length and low charge carrier mobilities. Therefore, the study of material properties and the interface modification are essential to improve the power efficiency of such devices. The goal of this work is to investigate heterojunctions of titanium dioxide (TiO2) and poly(3-hexyl thiophene) (P3HT) as active layers in hybrid photovoltaic devices. Such heterojunctions are attractive since the metaloxide can be nanostructured previous the infiltration of the polymer within the nanocrystalline phase, leading on large interfacial area with the possibility to tune the interfacial properties keeping the acceptor/donor character of the two components. Titania films were obtained from colloidal dispersions of anatase nanoparticles, while P3HT from its solution in 1,2-dichlorobenzene. The electrodes were indium-tin oxide (ITO) and gold (Au). Electrical and spectroscopic characterization shows the photovoltaic parameters, as well as absorption and photoluminescence, depends on post-production treatments, evidencing that heating induces conformational changes in the polymeric phase, changing the oxide/polymer interface. The introduction of carboxyl groups at 3-hexyl ramifications in P3HT permits better contacts between oxide and polymer by chemisorption, being favored by thermal treatment. Furthermore, the infiltration of the polymer within the nanocrystalline TiO2 leads on enhanced stability of the devices, working even six months after their preparation. Finally, in this work is also proposed the utilization of a interface modifier based on zinc phtalocyanine complex, which has extended the device absorption window up to the red/ near infrared, increasing light harvesting, and a transport study related to photocarriers generation and recombination process was carried out by photoconductivity action spectra

Dióxido de titânio

Dispositivos fotovoltaicos híbridos

Polímeros conjugados

Conjugated polymers

Hybrid photovoltaic devices

Titanium dioxide

Development of coevaporated hybrid perovskite thin films for solar cells applications. / Elaboration de films de perovskites hybrides par coévaporation pour des applications photovoltaïques.

Dindault, Chloe

08 October 2019

Les pérovskites hybrides célèbrent cette année leurs 10e anniversaire dans le domaine du photovoltaïque. En plus de la progression inégalée des rendements des cellules solaires, les pérovskites ont des propriétés optoélectroniques ajustables et peuvent être fabriquées par des procédés bas coûts, ce qui en fait de sérieuses candidates pour les cellules solaires multijunctions. Le réseau cristallin caractéristique des pérovskites hybrides offre une certaine liberté, supportant l’introduction partielle de cations et d’ions halogénures multiples. L’ajustement de la composition d’un matériau pérovskite se traduit par un ajustement de ces propriétés électroniques dont notamment sa structure de bandes. En adaptant la composition il est possible d’obtenir un matériau pérovskite avec une bande interdite de 1,7 eV qui serait parfaitement adapté pour une cellule tandem à base de Silicium cristallin. Les films minces de pérovskites peuvent être fabriqués par une grande diversité de techniques de dépôt, à partir de précurseurs ‘bon marché’ (CH3NH3I et PbI2 par exemple), par des procédés à basse température. Même si la grande majorité des films de pérovskites sont obtenus par la méthode d’enduction centrifuge, celle-ci ne permet pas l’obtention de films homogènes, sur grandes surfaces et de façon répétable. Etant donné l’enjeu industriel qui attend les pérovskites et l’intérêt croissant pour les structures tandems Silicium/Pérovskite, les méthodes sans solvant semblent plus adaptées. Déjà très largement utilisé dans l’industrie des OLEDs, le procédé de coévaporation thermique semble constituer une solution commercialement viable. Publiée pour la première fois en 2013, la synthèse par coévaporation des pérovskites est pour le moment encore étudiée par peu de groupes, car nécessitant des équipements plus coûteux. La présente thèse vise à mettre en place et développer la technique de coévaporation pour la fabrication de films de pérovskites hybrides pour des applications en cellules solaires.Afin d’évaluer la faisabilité du procédé, nous avons commencé notre travail sur un réacteur de démonstration, ce qui nous a permis d’appréhender la réponse à la sublimation des deux précurseurs. Nous avons très vite identifié le comportement du sel organique CH3NH3I comme étant problématique car difficilement contrôlable (s’évaporant sous forme de « nuage »), comme nous l’avions lu dans la littérature. En six mois d’utilisation de ce réacteur, nous avons fabriqué des films de pérovskites ayant permis d’atteindre des rendements de 9% sur des cellules solaires, malheureusement avec une faible reproductibilité (que nous expliquons en partie par le caractère aléatoire de l’évaporation du composé organique CH3NH3I). Nous nous sommes trouvés dans l’incapacité de comprendre plus en profondeur le procédé à cause d’un manque de fonctionnalités de l’équipement. Grâce à ces différents retours d’expérience nous avons pu concevoir, en étroite collaboration avec l’équipementier, un réacteur semi-industriel dédié à la fabrication de films de perovskites par coévaporation. Suite à sa mise en place, nous nous somme focalisé sur la problématique de la reproductibilité dans nos expériences en essayant de diminuer l’impact du nuage organique. Bien que les efficacités atteintes en cellules solaires pour des films coévaporés fussent moindres que pour des films déposés par la technique classique d’enduction centrifuge, nous soupçonnions néanmoins une meilleure homogénéité des films obtenus par voie sèche. Nous avons ainsi intégré à cette thèse une étude comparative voie liquide/voie sèche par le biais d’une technique de spectromicroscopie rayons X en Synchrotron. / Hybrid perovskites celebrate this year their 10-year anniversary in the photovoltaic field. Besides the unprecedented rise in solar cells efficiencies, perovskite materials have tunable optical properties and can be manufactured at low cost, making them very promising candidates for the high efficiency, multijunction solar cells strategy. Perovskite crystal structure offers a relative degree of freedom, allowing the partial integration of multiple cations and halide ions. This chemical composition tuning translates into a bandgap tuning. Through fine chemical engineering, the 1.7 eV requirement for a c-Si-based tandem device can be achieved. Perovskite thin films can be prepared by a large variety of deposition techniques, from low cost precursors (CH3NH3I and PbI2 for instance), through low-temperature processes. While most of the reported works on perovskite thin films are based on the basic wet-process spincoating technique, this latter hardly allows large scale, homogeneous and reproducible deposition. With the future challenge of industrialization and the increasing interest for the Silicon/Perovskite tandem approach, solvent-free methods appear more suitable. Already widely implemented in the OLED industry, coevaporation stands as a viable option for perovskites’ future. Reported for the first time in 2013, coevaporated perovskites are still scarcely studied compared to wet-based techniques, requiring more expensive set ups. In the present thesis, we implemented and developed the coevaporation process to fabricate perovskite thin films for solar cells applications.Starting off on a proof-of-concept reactor to assess the feasibility of the technique, we got accustomed to the perovskite precursors behaviour and identify very early on the organic precursor to be hardly manageable, as reported in the literature. In six months, we were nonetheless able to obtain nice perovskite films leading to 9% efficient photovoltaic devices, unfortunately with a poor reproducibility that we think to be partially due to the cloud vapour behaviour of CH3NH3I. We eventually found ourselves missing some features on the equipment, preventing us from accurately get a grasp on the process. From this feedback we then designed, hand in hand with the manufacturer, a dedicated semi-industrial equipment for perovskite coevaporation. Following its implementation, we then focused on establishing the reproducibility of the method, trying to mitigate the parasitic effect of the organic compound. Even though the efficiencies in solar cells were still slightly lower for coevaporated perovskites, with respect to classical spincoated ones, we expected the material homogeneity to be in favour of the vacuum-based process. We then eventually integrated to this thesis a comparative study between wet- and dry-processed perovskite films using a Synchrotron-based X-ray spectromicroscopy technique.

Pérovskites

Dispositifs photovoltaïques

Procédé sous vide

Synchrotron

Perovskites

Photovoltaic devices

Vacuum process

Synchrotron

621.312 44

Studies of nano-carbon hole transport layer for high performance photovoltaic devices / ナノカーボンホール輸送層を利用した高性能太陽電池デバイスに関する研究

Wang, Feijiu

23 March 2016

京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第19829号 / エネ博第335号 / 新制||エネ||67(附属図書館) / 32865 / 京都大学大学院エネルギー科学研究科エネルギー応用科学専攻 / (主査)教授 松田 一成, 教授 佐川 尚, 教授 大垣 英明 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DGAM

Carbon nanotubes

Hole transport layer

Photovoltaic devices

Schottky barrier

Solar cell

501

Processing And Study Of Carbon Nanotube / Polymer Nanocomposites And Polymer Electrolyte Materials

Harish, Muthuraman

01 January 2007

The first part of the study deals with the preparation of carbon nanotube/polymer nanocomposite materials. The dispersion of multi-walled carbon nanotubes (MWNTs) using trifluoroacetic acid (TFA) as a co-solvent and its subsequent use in polymer nanocomposite fabrication is reported. The use of carbon nanotube/ polymer nanocomposite system for the fabrication of organic solar cells is also studied. TFA is a strong but volatile acid which is miscible with many commonly used organic solvents. Our study demonstrates that MWNTs can be effectively purified and readily dispersed in a range of organic solvents including dimethyl formamide (DMF), tetrahydrofuran (THF), and dichloromethane when mixed with 10 vol% trifluoroacetic acid (TFA). X-ray photoelectron spectroscopic analysis revealed that the chemical structure of the TFA-treated MWNTs remained intact without oxidation. The dispersed carbon nanotubes in TFA/THF solution were mixed with poly(methyl methacrylate) (PMMA) to fabricate polymer nanocomposites. A good dispersion of nanotubes in solution and in polymer matrices was observed and confirmed by SEM and optical microscopy study. Low percolation thresholds of electrical conductivity were observed from the fabricated MWNT/PMMA composite films. A carbon nanotube/ polymer nanocomposites system was also used for the fabrication of organic solar cells. A blend of single-wall carbon nanotubes (SWNTs) and poly3-hexylthiophene (P3HT) was used as the active layer in the device. The device characteristics showed that the fabrication of the solar cells was successful without any shorts in the circuit. The second part of the study deals with the preparation and characterization of electrode and electrolyte materials for lithium ion batteries. A system of lithium trifluoroacetate/ PMMA was used for its study as the electrolyte in lithium battery. A variety of different processing conditions were used to prepare the polymer electrolyte system. The conductivity of the electrolyte plays a critical role in the high power output of a battery. A high power output requires fast transport of lithium ions for which the conductivity of the electrolyte must be at least 3 x 10^-4 S/cm. Electrochemical Impedance Spectroscopy (EIS) was used to determine the conductivity of the polymer electrolyte films. Among the different processing conditions used to prepare the polymer electrolyte material, wet films of PMMA/salt system prepared by using 10vol% of TFA in THF showed the best results. At about 70wt% loading of the salt in the polymer, the conductivity obtained was about 1.1 x 10^-2 S/cm. Recently, the use of vanadium oxide material as intercalation host for lithium has gained widespread attention. Sol-gel derived vanadium oxide films were prepared and its use as a cathode material for lithium ion battery was studied. The application of carbon nanotubes in lithium ion battery was explored. A carbon nanotube /block copolymer (P3HT-b-PS) composite was prepared and its potential as an anode material was evaluated.

Carbon nanotubes

nanocomposites

percolation threshold

photovoltaic devices

polymer electrolyte materials

Engineering

Materials Science and Engineering

A study of the suitability of amorphous, hydrogenated carbon (a-C:H) for photovoltaic devices

Maldei, Michael

January 1997

No description available.

Engineering, Chemical

amorphous

hydrogenated carbon (a-C:H)

photovoltaic devices

elastic recoil spectroscopy

optical bandgap energy

Titania Nanostructures for Photocatalytic and Photovoltaic Applications

Chaudhary, Aakanksha

January 2015

Titania has been the focus of attention for several decades owing to its chemical stability, non-toxicity, inexpensiveness and robust surface chemistry. Its technological applications include use in diverse areas such as photocatalytic reactors, antibacterial coatings, dye sensitive solar cells (DSSC) and more recently the perovskite solar cells to name a few. All of these applications are based on the ability to inject or generate electronhole pairs in titania and transport them to a suitable interface at which they are ejected to either engender a reaction as in photocatalysis or drive a load as in photovoltaics. From a technological perspective it is also important that such science be achieved and controlled in supported titania structures. The research reported in this thesis, thus, started with the development of a process for obtaining adherent titania films by oxidation of sputtered Ti films on stainless steel, a very commonly used substrate. Challenges that had to be overcome included the need to oxidize titanium to obtain the right phase mixture while preventing film cracking or delamination due to compressive stresses generated during anodic oxidation of Ti. During this process of obtaining nanostructured TiO2 through anodization, it was serendipitously discovered that planar TiO2 films obtained by oxidation of sputtered Ti films did significantly better than anodized nanoporous titania in bactericidal studies. This was then replicated in organic dye degradation studies. Analysis of the material showed that this improved performance was due to the unintentional contamination during sputtering by Cu, Zn, Mo possibly due to arcing across brass contacts. This quaternary system was then systematically explored and it was shown that an optimal metastable composition in the Ti- Cu-Mo oxide ternary system performs the best. DFT studies showed that this was due to introduction of shallow and deep states in the band gap that, depending on the level of dopants, either enhances carrier lifetimes or leads to recombination. In continuation of this work on supported titania structures by oxidation of Ti, a novel photoanode for use in dye sensitized photovoltaics was developed by oxidation of Ti foam. This results in an interconnected 3-D network of TiO2 that possess at its core a network of Ti. Such architecture was designed to provide a large surface area for anchoring the sensitizer while simultaneously reducing the distance that charge carriers have to travel before reaching the ohmic contacts to prevent recombination losses. The thesis discusses the preparation of such anodes, the properties of the 3-D oxide and cells, with up to 4% efficiency, developed using such anodes. Reasons for such behaviour and avenues for further exploration to improve cell efficiency will also be discussed.

Titanium Nanostructures

Photocatalysis

Photovoltaics

Nanostructued Titanium Dioxide Films

Photovoltaic Devices

Dye Sensitized Solar Cells (DSSC)

Nanostructured Titanianium Oxide

Titanium Photoanodes

Nanostructured Photocatalytic Titania

Photoenergy

Adherent Titania Films

Nanostructured TiO2

Titania Nanostructures

Materials Science

CdTe/CdSe/CdTe heterostructure nanorods and I-III-VI₂ nanocrystals: synthesis and characterization

Koo, Bonil

21 June 2010

Semiconductor nanocrystals are interesting candidates as new light-absorbing materials for photovoltaic (PV) devices. They can be dispersed in solvents and cheaply deposited at low-temperature on various substrates. Also, the nanocrystals have unique optical properties depending on their size due to the quantum size effect and moreover it is easy to uniformly control their stoichiometry. CdTe/CdSe/CdTe heterostructure nanorods and I-III-VI₂ nanocrystals were selected to synthesize and investigate in order to utilize the benefits of colloidal nanocrystals described above. Colloidal nanorods with linear CdTe/CdSe/CdTe heterojunctions were synthesized by sequential reactant injection. After CdTe deposition at the ends of initially formed CdSe nanorods, continued heating in solution leads to Se-Te interdiffusion across the heterojunctions and coalescence to decreased aspect ratio. The Se-Te interdiffusion rates were measured by mapping the composition profile using nanobeam energy dispersive X-ray spectroscopy (EDS). The rate of nanorod coalescence was also measured and compared to model predictions using a continuum viscous flow model. The synthetic method of monodisperse chalcopyrite (tetragonal) CuInSe₂ nanocrystals was also developed. The nanocrystals have trigonal pyramidal shape with one polar and three non-polar surface facets. When drop-cast onto carbon substrates, the nanocrystals self-assemble into close-packed monolayers with triangular (honeycomb) lattice structure. Moreover, the effect of excess Cu precursor (CuCl) was studied for the formation of monodisperse trigonal pyramidal CuInSe₂ nanocrystals. The formation mechanism of monodisperse trigonal pyramidal CuInSe₂ nanocrystals was suggested with regard to excess amount of CuCl precursor, based on the nucleationgrowth model of colloidal nanocrystal formation. A new wurtzite phase of CuInS₂, CuInSe₂, and Cu(InxGa1-x)Se₂ (CIGS) was observed in nanocrystals synthesized by heating metal precursors and Se-(or S-)urea in alkylamine. X-ray diffraction (XRD) showed the predominant phase to be wurtzite (hexagonal) instead of chalcopyrite (tetragonal). High resolution transmission electron microscopy (TEM), however, revealed polytypism in the nanocrystals, with the wurtzite phase interfaced with significant chalcopyrite domains. / text

Nanorods

Nanocrystals

Photovoltaic devices

Stoichiometry

CdTe/CdSe/CdTe heterostructure nanorods

I-III-VI₂ nanocrystals

CuInSe₂ nanocrystals

Wurtzite

Chalcopyrite

IMIDE-FUNCTIONALIZED CONJUGATED POLYMERS: SYNTHESIS, STRUCTURE-PROPERTY AND DEVICE STUDIES

Guo, Xugang

01 January 2009

Organic semiconductors are widely studied as potential active components for consumer electronics due largely to their easily tuned properties and the promise of lower-cost solution-based processing technology. Imide-functionalized organic small molecule compounds have been one of the more important and studied organic semiconductors. However, very few imide-functionalized conjugated polymers have been reported in the literature. The body of this dissertation focuses on the synthesis, structure-property and device studies of imide-functionalized conjugated polymers. Reasons for choosing arylene imides as polymer building blocks include: a) they impart low-lying LUMOs to polymers, allowing band-gap engineering through choice of comonomers with variable electron-donating ability; b) imide-nitrogens provide points to attach side chains to manipulate solubility and solid-state packing; c) they are easily prepared. Structure-property studies include electrochemical measurements, UV-Vis absorption spectroscopy, differential scanning calorimetry (DSC), x-ray diffraction, and in some cases evaluation as active components in field-effect transistors (OFETs) and photovoltaic devices (PVDs). The published method to synthesize 3,6-dibromo-pyromellitic bisimides (PMBI) was streamlined and poly(phenylene ethynylene)s (PPEs) with variable band gaps were prepared from them (Chapter 2). As noted in all the chapters, electrochemical and optical measurements reveal that the LUMO of the polymers is indeed dictated by the arylene imide, while the HOMO, and therefore the optical energy gap is controlled through varying the electron donor monomer. Intramolecular hydrogen bonding was employed for increasing backbone coplanarity and therefore the polymer could have higher conjugation. One of these polymers demonstrated the narrowest band gap (1.50 eV) for any published PPE. Chapter 3 describes the first published conjugated copolymers from naphthalene bisimides (NBI), here using thiophene-based comonomers as donor units. Polymers with high molecular weight and decent solubility were obtained by choosing appropriate side chains. The optical energy gaps could be tuned across the visible and into the near IR. Preliminary OFET studies revealed electron mobility as high as ~0.01 cm2/Vs. One low band gap polymer provided OFETs with electron mobility of ~0.04 cm2/Vs and hole mobility of ~0.003 cm2/Vs, which is also among the highest mobilities of ambipolar polymeric semiconductors. Using the same approach as in Chapter 3, phthalimide-based monomers were incorporated into polymer backbones for developing new high performance p-type polymer semiconductors for OFETs and PVDs (Chapter 4). Some analogues based on benzothiadiazole, PMBI, and thiophene imides as acceptors were prepared for comparison. Again, high molecular weight, soluble polymers with band gaps spanning the visible and into the near IR were obtained. OFETs from one of the polymers yielded hole mobility ~0.3 cm2/Vs under ambient atmosphere without post-processing thermal annealing, which places it squarely within the state-of-the-art for conjugated polymers. Due to the high mobility and low band gap, this polymer also leads to PVDs with moderately good power conversion efficiency (PCE: ~2%).

Chemistry