Global ETD Search

61	Estudo das camadas transportadoras de elétrons em dispositivos poliméricos emissores de luz. / Electron transport layer study in polymeric light emission devices. Helena Liberatori Gimaiel 15 October 2008 (has links) Este trabalho tem como objetivo o estudo de camadas transportadoras de carga, em especial de elétrons, em dispositivos poliméricos emissores de luz (PLEDs). Estes dispositivos são obtidos basicamente através da deposição de uma camada emissiva polimérica entre dois eletrodos. Dispositivos poliméricos luminescentes apresentam vantagens quando comparados aos LEDs convencionais, entre elas a possibilidade de fabricação de mostradores ultrafinos, com baixo custo de fabricação e flexíveis. A eficiência dos PLEDs está intimamente ligada a viabilidade de comercialização destes displays. Neste trabalho, a primeira estrutura confeccionada é formada pela deposição de um filme do polímero emissivo OC1C10 PPV - poly[2-metoxi-5-(3,7-dimetiloctiloxi)- 1,4-fenilenovinileno entre o anodo ITO (Oxido de Índio-Estanho) e o catodo alumínio. Sobre o eletrodo transparente ITO o polímero OC1C10-PPV e o Al são depositados sob forma de filme através das técnicas Spin Coating e Evaporação Térmica, respectivamente. Em uma segunda etapa, foram fabricadas amostras com uma estrutura diferenciada, de modo que foram introduzidas camadas de filmes relacionadas aos fenômenos de transporte de cargas capazes de aumentar a eficiência do dispositivo. Estas camadas são responsáveis por uma redução da barreira de potencial existente entre o polímero emissivo e os eletrodos e podem também confinar um número maior lacunas no interior da camada emissiva. Este feito implica num aumento da população de elétrons e lacunas no interior da camada ativa, gerando uma maior recombinação de cargas. Neste sentido, filmes de Alq3 (tris-(8-hydroxyquinolate)-aluminum) com diferentes espessuras foram introduzidos entre a camada ativa e o catodo, gerando uma emissão luminosa superior. Por fim, diferentes concentrações de Alq3 foram adicionadas à solução de OC1C10-PPV, resultando em compostos OC1C10-PPV:Alq3 utilizados como camada ativa, o que proporcionou um aumento da eficiência luminosa em mais de 10 vezes quando comparado aos dispositivos fabricados na primeira etapa do trabalho. A utilização do polímero PEDOT:PSS - Poli (3,4-etilenodioxitiofeno) : Poliestireno Sulfonado- como camada transportadora de lacunas (HTLs) depositada entre o alumínio e o polímero eletroluminescente se mostrou indispensável para o funcionamento dos dispositivos fabricados, evitando o curto circuito entre eletrodos. / This work has the objective to study charge carried layers, especially of electrons, in polymer light emitting devices (PLEDs). These devices are obtained basically by polymer emissive layer deposition between two electrodes. Polymer luminescent devices show advantages when compared to conventional LEDs, such as the thin displays manufacture possibility, with low cost of manufacture and flexible. The PLEDs efficiency is closely linked the commercialization feasibility these displays. In this work, the first structure fabricated is composed by the deposition of OC1C10 PPV - [poly(2-(3,7-dimethyloctyloxy)-5-(2\'-methoxy-1,4-phenylene vinylene)] emissive polymer film between the anode ITO (Indium Tin Oxide) and the aluminum cathode. On the transparent electrode ITO the polymer OC1C10-PPV and Al are deposited as a film through spin coating and thermic evaporation techniques, respectively. In other step, samples were fabricated with a differentiated structure, which films layers related to charges transport were introduced and increase efficiency device. These layers are responsible for reduction of potential barrier between polymer emissive and the electrodes and they can confine a higher number of holes in the emissive layer. This imply in an increase of electrons and hole population in active layer, producing a higher luminous emission. Finally, different Alq3 concentrations were added to solution of the OC1C10-PPV, resulting in compost OC1C10-PPV:Alq3 used as active layer, that increase the luminous efficiency more 10 times than the devices fabricated in first stage of this work. The use polymer PEDOT:PSS Poly(3,4-ethylenedioxythiophene): Poly(StyreneSulfonate) as hole transport layer (HTLs) deposited between the aluminum and the polymer electroluminescent showed essential to operation of devices produced, avoiding the short circuit between electrodes. Displays Eletrônica molecular ETL Microeletrônica Nanotecnologia PLED Alq3 ETLs OC1C10-PPV PLEDs
62	Calcium vapour deposition on semiconducting polymers studied by adsorption calorimetry and visible light absorption Hon, Sherman Siu-Man 11 1900 (has links) A novel UHV microcalorimeter has been used to study the interaction between calcium and three polymers: MEH-PPV, MEH-PPP and P3HT. All three polymers behave differently in their reaction kinetics with calcium. On MEH-PPV we measure 45 μJ/cm² of heat generated in excess of the heat of bulk metal growth, 120 μJ/cm² for MEH-PPP, and 100 μJ/cm² for P3HT. Comparison of the MEH-PPV and MEHPPP data indicate that the initial reaction of calcium with MEH-PPV occurs at the vinylene group. We propose, based on hypothetical models, that calcium reacts with the vinylene groups of MEH-PPV with a reaction heat of 360 kJ/mol and at a projected surface density of 1.7 sites/nm², while it reacts with the phenylene groups of MEH-PPP in a two-step process with reaction heats of 200 and 360 kJ/mol respectively, at a projected surface density of 3.5 sites/nm². Optical absorption experiments, using either a 1.85 eV diode laser or a xenon lamp coupled to a scanning monochromator, have also been performed using the same calorimeter sensor. In the case of MEH-PPV, using the laser we find an optical absorption cross-section of 3E-¹⁷ cm² per incident calcium atom at low coverages. The change in absorptance at higher coverages correlates perfectly with the population of reacted Ca atoms determined calorimetrically. The size of the absorbance cross-section, and its position just within the band gap of the polymer, are consistent with the reaction being one of polaron formation. Calcium does not appear to dope P3HT, while the photon energy range of 1.5 to 3.75 eV used in these experiments is likely too small for probing polaronic energy states in MEH-PPP. / Science, Faculty of / Chemistry, Department of / Graduate Calorimetry Physical chemistry Surface science Semiconducting polymers Polymer metallization MEH-PPV MEH-PPP P3HT
63	Technologie využívající organických materiálů / Technologies using organic materials Galbička, Tomáš January 2014 (has links) There are sumarized some of the basic organic materials for produce of organic parts. Two types of theese materials are introduced PPV and PFV and their derivatives, which tuning their resulting properties in area of electrical, optical, chemical, and thermal parameters. There is designed and created system for mechanical bending of adhesive SMD devies on flexible printed circuit board and compared properties of some conducting adhesives.
64	Numerical Modeling of Dynamic Compaction in Cohesive Soils Mostafa, Khaled F. 26 October 2010 (has links) No description available. Civil Engineering Void Ratio Crater Depth tamping SOILS tamper crater PPV
65	The Synthesis of Benzyloxy Substituted DP-PPV and Examination of the Horner-Wadsworth-Emmons Reaction in the Synthesis of DP-PPV Lear, Jeremy M. 04 June 2014 (has links) No description available. Chemistry Polymers Polymer Chemistry
66	Synthesis of Poly(p-phenylene vinylene) within Faujasite and Linde Type A Zeolites: Encapsulation for Improved Optical Properties Heck, Elizabeth Maria 22 July 2011 (has links) No description available. Alternative Energy Analytical Chemistry Chemistry zeolite PPV encapsulation conductive polymers host-guest chemistry
67	Analysis of electrogenerated chemiluminescence of PPV type conducting polymers Janakiraman, Umamaheswari 20 May 2003 (has links) Mit Lösungen von 9,10-Diphenylanthracen und N(C2H5)4ClO4 oder N(C4H9)4ClO4 als Leitsalz im Lösungsmittel Acetonitril wurden Elektrochemilumineszenz (ECL)-Experimente durchgeführt. Dazu wurden die Elektroden mit Folgen von jeweils drei in bestimmten zeitlichen Abständen aufeinander folgenden Potentialsprüngen polarisiert. Es wird gezeigt, dass bei entsprechender Wahl der Potentiale und der Haltezeiten anodische und kathodische ECL-Emissionen gleicher Intensität erzeugt werden können. Sodann wurde ECL in den Derivaten von Poly(p-phenylen-vinylen), MEH-PPV und DB-PPV erzeugt. Diese leitfähigen Polymere wurden als dünne Schichten auf Platin-Elektroden aufgebracht und wie bei ECL aus der Lösungsphase in Acetonitril-Elektrolyten mit Tetralkylammonium-Leitsalzen Potentialsprüngen unterworfen. Bei geeigneter Einstellung der Potentialsprünge und Haltezeiten konnten anodische und kathodische ECL gleicher Intensität erhalten werden. Dies ist das erste Mal, dass symmetrische ECL mit polymerbeschichteten Elektroden erhalten wurde. Die Kinetik der ECL weicht deutlich von der aus der Lösungsphase ab. Der ECL-Prozess verläuft langsamer als in der Lösungsphase, und der Leitelektrolyt hat einen signifikanten Einfluss auf das elektrochemische Verhalten der Polymerschicht. Die Ursachen dafür wurden über Modellrechnungen analysiert, mit denen die Ladungstransportprozesse in der Polymerschicht simuliert wurden. In derartigen Simulationsrechnungen konnten die Geschwindigkeitskonstanten der ECL-Reaktion sowohl im Polymer als auch in der Lösung bestimmt werden. Um die Stabilität der Polymerschichten zu erhöhen, wurde versucht, die Polymerketten mit Synchrotronstrahlung zu vernetzen. Diese Experimente brachten nicht das erwartete Ergebnis. Die Ursachen dafür werden auf der Grundlage von Ex-Situ-Raman-spektroskopischen Untersuchungen diskutiert. / Electrochemiluminescence (ECL) has been generated in solution phase using 9,10-diphenylanthracene (DPA) with TEAClO4 (or TBAClO4) in acetonitrile solvent. Triple potential step was used for the generation of ECL. It was found that anodic and cathodic ECL of equal intensities can be generated by proper choice of potential step magnitude, width and the waiting period (tw) between successive triple potential steps. ECL was then generated in conducting polymers poly(2-ethylhexyloxy-5-methoxy-1,4-phenylenevinylene) (MEH-PPV) and poly(2,3-dibutoxy-1,4-phenylenevinylene) (DB-PPV) by coating them on Pt electrodes and subjecting to potential steps in tetraalkylammonium salt solutions with acetonitrile. Similar to the case of solution phase ECL, symmetrical anodic and cathodic ECL could be observed by the appropriate choice of the potential step parameters. But the kinetics of the ECL was found to be different from that of the solution phase ECL. The time scale of the ECL process was found to be longer than that in the solution phase ECL. The nature of supporting electrolyte had a remarkable impact on the electrochemistry of conducting polymers. The reasons were analyzed by theoretical calculations evoking the concept of charge transport characteristics of conducting polymers. The rate constants of the ECL process were calculated by separate simulation procedure in the solution phase as well as in the polymer phase ECL. To enhance the stability of conducting polymers, synchrotron radiation induced cross-linking was performed. The effects were different from expected which were analyzed and rationalized by ex-situ Raman spectroscopic studies. Elektrochemilumineszenz (ECL) 9,10-diphenylanthracen (DPA) Polymere MEH-PPV DB-PPV Potentialsprung experiment Raman spectroskopy Electrogenerated chemiluminescence (ECL) 9,10-diphenylanthracene (DPA) conjugated polymers MEH-PPV DB-PPV triple potential step experiments Raman spectroscopy synchrotron induced cross-linking 30 Chemie VK 5660 ddc:540
68	Excitonic behaviour in polymeric semiconductors : the effect of morphology and composition in heterostructures Rezasoltani, Elham 01 1900 (has links) La compréhension des interrelations entre la microstructure et les processus électroniques dans les polymères semi-conducteurs est d’une importance primordiale pour leur utilisation dans des hétérostructures volumiques. Dans cette thèse de doctorat, deux systémes diffèrents sont étudiés ; chacun de ces systèmes représente une approche diffèrente pour optimiser les matériaux en termes de leur microstructure et de leur capacité à se mettre en ordre au niveau moléculaire. Dans le premier système, j’ai effectué une analyse complète des principes de fonctionnement d’une cellule photovoltaïque hybride à base des nanocristaux d’oxyde de zinc (ZnO) et du poly (3-hexylthiophène) (P3HT) par absorption photoinduite en régime quasi-stationnaire (PIA) et la spectroscopie PIA en pompage modulé dépendant de la fréquence. L’interface entre le donneur (le polymère P3HT) et l’accepteur (les nanoparticules de ZnO), où la génération de charges se produit, joue un rôle important dans la performance des cellules photovoltaïques hybrides. Pour améliorer le mécanisme de génération de charges du P3H: ZnO, il est indispensable de modifier l’interface entre ses constituants. Nous avons démontré que la modification d’interface moléculaire avec cis-bis (4, 40 - dicarboxy-2, 20bipyridine) ruthénium (II) (N3-dye) et a-Sexithiophen-2 yl-phosphonique (6TP) a améliorée le photocourant et la performance dans les cellules P3HT: ZnO. Le 6TP et le N3 s’attachent à l’interface du ZnO, en augmentant ainsi l’aire effective de la surface donneur :accepteur, ce qui contribue à une séparation de charge accrue. De plus, le 6TP et le N3 réduisent la densité de pièges dans le ZnO, ce qui réduit le taux de recombinaison des paires de charges. Dans la deuxième partie, jai introduit une matrice hôte polymérique de polystyréne à masse molaire ulra-élevée, qui se comporte comme un solide pour piéger et protéger une solution de poly [2-méthoxy, 5- (2´-éthyl-hexoxy) -1,4-phénylènevinylène- PPV] (MEHPPV) pour utilisation dans des dispositifs optoèlectroniques quantiques. Des travaux antérieurs ont montré que MEH-PPV en solution subit une transition de conformation, d’une conformation enroulé à haute température (phase bleue) à une conformation de chaîne étendue à basse température (phase rouge). La conformation de la chaîne étendue de la solution MEH-PPV favorise les caractéristiques nécessaires à l’amélioration des dispositifs optoélectroniques quantiques, mais la solution ne peut pas être incorporées dans le dispositif. J’ai démontré que la caractéristique de la phase rouge du MEH-PPV en solution se maintient dans une matrice hôte polymérique de polystyrène transformé de masse molaire très élevée, qui se comporte comme un solide (gel de MEH-PPV/UHMW PS), par le biais de la spectroscopie de photoluminescence (PL) dépendant de la température (de 290K à 80 K). La phase rouge du gel MEH-PPV/UHMW PS se manifeste par des largeurs de raie étroites et une intensité augmentée de la transition 0-0 de la progression vibronique dans le spectre de PL ainsi qu’un petit décalage de Stokes entre la PL et le spectre d’absorption à basse température. Ces approches démontrent que la manipulation de la microstructure et des propriétés électroniques des polymères semi-conducteurs ont un impact direct sur la performance de dispositifs pour leurs développements technologiques continus. / Understanding the interrelations between microstructure and electronic processes in polymeric semiconductors is of great importance for their use in bulk heterostructures, as the active part of power-converting devices such as organic photovoltaic cells or light emitting diodes, as well as for quantum optoelectronics applications. In this doctoral thesis, two different systems are investigated; each of these systems represents a different approach to optimize materials in terms of microstructure and their ability to order on the molecular level. In the first system, by means of quasi-steady-state photoinduced absorption (PIA) and pump-modulation-frequency-dependent PIA spectroscopy, I performed a comprehensive analysis of the working principles of a hybrid photovoltaic cell based on nanocrystals of zinc oxide (ZnO) and poly(3-hexylthiophene) (P3HT). The interface surface area between donor (polymer P3HT) and acceptor (ZnO nanocrystals), where charge generation occurs, plays a significant role in the performance of the hybrid photovoltaic cells. To improve the charge generation mechanism of P3HT: ZnO, it is therefore essential to modify the P3HT: ZnO interface area. We demonstrated that molecular interface modification with cis-bis(4,40-dicarboxy-2,20bipyridine) ruthenium (II) (N3-dye) and a-Sexithiophen-2-yl-phosphonic Acid (6TP) as interface modifiers enhanced the photocurrent and performance in P3HT: ZnO cells. 6TP and N3 attach to the ZnO interface, thus increasing the donor:acceptor interface area that contributes to enhanced charge separation. Furthermore, 6TP and N3 reduce the ZnO traps that reduces recombination. In the second part, I introduced a processed solid-like ultra-high-molecular-weight polystyrene polymeric host matrix to trap and protect poly [2-methoxy, 5-(2’-ethylhexoxy)- 1,4-phenylene vinylene-PPV] (MEH-PPV) solution for use in quantum optoelectronic devices. Previous work by others has shown that MEH-PPV in solution undergoes a conformation transition from coiled conformation at high temperatures (blue-phase) to a chain-extended conformation at low temperatures (red-phase). The chain-extended conformation of MEH-PPV solution favours the characteristics needed to improve quantum optoelectronic devices, however the solution cannot be incorporated into the device. We demonstrated that the red-phase feature of MEH-PPV in solution maintains in a processed solid-like ultra-high-molecular-weight polystyrene polymeric host matrix (MEH-PPV/UHMWPS gels), by means of temperature-dependent photoluminescence (PL) spectroscopy (ranged from 290K down to 80 K). The red-phase of MEH-PPV/UHMW PS gels manifest itself as narrow linewidths and enhanced 0-0 line strength in the PL spectrum as well as a small stokes shifts between the PL and absorption spectra at low temperatures. These approaches demonstrate that microstructure manipulation and electronic properties of polymeric semiconductors have a direct impact on the device performance for their continued technological developments. Polymères semi-conducteurs Exciton Polaron Microstructure Modification d’interface Spectroscopie P3HT: ZnO MEH-PPV Photoluminescence Absorption photoinduite Polymeric semiconductors Exciton Polaron Microstructure Interface modification Spectroscopy P3HT: ZnO MEH-PPV Photoluminescence Photoinduced absorption
69	Processamento de poli(p-fenilenovinileno) (PPV) com pulsos laser de femtossegundos: fabricação de microestruturas óptica e eletricamente ativas / Processing of poly (p-phenylenevinylene) (PPV) with femtosecond laser pulses: fabrication of optically and electrically active microstructures Salas, Oriana Ines Avila 12 July 2018 (has links) O poli (p-fenilenevinileno), ou PPV, é um polímero de grande relevância tecnológica devido a suas propriedades eletroluminescentes, que têm sido exploradas em diodos emissores de luz orgânicos, displays flexíveis e outros dispositivos optoeletrônicos. Embora o PPV seja um material de importância para muitas aplicações, a sua síntese na nano/microescala não pode ser obtida através do método padrão, o qual utiliza o aquecimento de um polímero precursor poli (cloreto de xileno tetrahidrotiofenio) (PTHT). Este trabalho mostra como a microestruturação com pulsos de femtosegundo pode ser empregada para a síntese de PPV em regiões pré-determinadas, empregando três diferentes abordagens, permitindo uma nova metodologia para a fabricação precisa de microcircuitos poliméricos complexos, (i) na primeira abordagem, o processo de conversão é obtido pela irradiação de filmes de PTHT com pulsos laser ultracurtos em regiões previamente determinadas, o que leva ao controle espacial da formação de PPV em microescala, (ii) na segunda abordagem, microestruturas tridimensionais dopadas com PTHT foram fotopolimerizadas por absorção de dois fótons. A conversão de PTHT para PPV nestas microestruturas dopadas foi obtida após um tratamento térmico, (iii) na terceira abordagem, a transferência direta induzida por laser (LIFT) com pulsos de femtossegundos permite a deposição controlada de PPV com alta resolução espacial, fornecendo micropadrões 2D, preservando sua estrutura e propriedades ópticas. As estruturas foram caracterizadas por microscopia eletrônica de varredura, microscopia óptica de transmissão, microscopia de fluorescência e microscopia confocal de fluorescência. Suas propriedades ópticas foram analisadas através de sistemas de micro-fotoluminescência e micro-absorção implementadas em um microscópio invertido. Medidas de espectroscopia Raman, microscopia de força atômica e medidas elétricas também foram realizadas. Este trabalho mostra como a microestruturação com laser de fs pode ser explorada para a síntese de PPV em regiões pré-determinadas para fabricar uma variedade de microdispositivos, abrindo novos caminhos na optoeletrônica baseada em polímeros. / Poly(p-phenylenevinylene), or PPV, is a polymer of great technological relevance due to its electroluminescent properties, which have been exploited in organic light emitting diodes, flexible displays and other optoelectronic devices. Although PPV is a material of foremost importance for many applications, its synthesis at the nano/micro scale cannot be achieved through the standard method that uses heating of a precursor polymer poly(xylene tetrahydrothiophenium chloride)(PTHT). This work demonstrates the use of direct laser writing with femtosecond pulses to obtain the synthesis of PPV in pre-determined regions, by applying three different approaches, allowing the precise fabrication of complex polymeric microcircuits, (i) in the first approach the conversion process is achieved by irradiating PTHT films with ultra-short laser pulses in previously determined regions, which leads to the spatial control of PPV formation at microscale, (ii) in the second approach, three-dimensional microstructures doped with PTHT were photopolymerized by two photons absorption. The conversion of PTHT to PPV in these doped microstructures was obtained by a subsequent thermal treatment, (iii) in the third approach, laser-induced forward transfer (LIFT) with femtosecond pulses enables the controlled deposition of PPV with high spatial resolution, providing 2D micropatterns, while preserving its structure and optical properties. The structures were characterized by scanning electron, fluorescence, transmission and confocal fluorescence microscopies. Their optical properties were analyzed by micro-photoluminescence and micro-absorption setups assembled on an inverted microscope. Raman spectroscopy, electrical measurements and atomic force microscopy were also performed. This thesis shows the use of fs-laser writing methods for the synthesis of PPV in pre-determined regions, to fabricate a variety of microdevices, thus opening new avenues in polymer-based optoelectronics. Absorção de dois fótons Direct-laser writing Femtosecond laser pulses Laser de femtosegundos Laser induced forward transfer (LIFT) Microestructuração a laser Poli (p-fenileno vinileno) (PPV) Poly(p-phenylene vinylene) (PPV) Two-photon absorption
70	Novos poli(p-xilileno)s e poli(p-fenileno vinileno)s obtidos via quinodimetanos gerados catodicamente / Novel poly(p-xylylene) s and poly (p-phenylene vinylene) are obtained via cathodically generated quinodimethanes Li, Rosamaria Wu Chia 14 November 2002 (has links) Esta tese envolveu a síntese de 11 precursores poliméricos inéditos, derivados de bifenilos e terfenilos, substituídos por grupos receptores e doadores de elétrons, por meio de reações de acoplamento de Suzuki. Tais precursores foram convertidos aos respectivos polímeros, poli(p-xilileno)s e poli(p-fenileno vinileno)s, via redução catódica, conduzindo a um total de 11 polímeros, sendo dez deles inéditos. Os polímeros obtidos foram caracterizados por métodos espectroscópicos (UV-VIS, IV, RMN), análises térmicas, SEC e medidas de condutividade elétrica pós-dopagem. Um dos polímeros foi empregado na construção de dispositivos metal/polímero/metal (\"sanduíche\"), que permitiram a determinação da mobilidade dos portadores de carga, bem como da altura de barreira para injeção de elétrons na junção metal/polímero. / The synthesis via Suzuki coupling reaction of 11 new biphenylenic and terphenylenic polymer precursors, substituted by long-chain electron donating or withdrawing groups, is described. The electrochemical reduction of these precursors led to the corresponding poly(p-xylylene)s and poly(p-phenylene vinylene)s. Ten out of the 11 generated polymers have been never described before. AII the polymers were fully characterised by spectroscopic (UV-VIS, IR, NMR) and thermal analyses, as well as by SEC and electrical conductivity measurements of iodine-doped specimens. The positive charge carrier mobility and the barrier height for electron injection (metal/polymer) could be determined through I x V investigations of sandwich devices (metal/polymer/metal) for one of the polymers. Conductive polymers Electrochemical synthesis Organic chemistry Poli p-fenilenovinileno Poli p-terfenilenovinileno Polímeros (Química orgânica) Polímeros condutores Poly p-phenylenevinylene Poly p-terphenylene vinylene Polymers (Organic chemistry) PPV PPV PPX PPX Química orgânica Síntese eletroquímica

Search results