Global ETD Search

31	Tuning The Optoelectronic Properties Of Conjugated Polymers Via Donor-acceptor-donor Architectures Tarkuc, Simge 01 June 2010 (has links) (PDF) A new class of &amp / #960 / -conjugated monomers was synthesized with combination of electron donating and electron-withdrawing heterocyclics to understand the effects of structural differences on electrochemical and optoelectronic properties of the resulting polymers. The use of this alternating donor-acceptor-donor strategy allows the synthesis of low band gap polymers in which the redox, electronic, and optical properties are controlled through easily approachable synthetic modification of the polymer backbone. This control allows fine-tuning of the band gap to values between 1.0 and 1.8 eV by making structural changes. These structural manipulations yield varied electronic absorption energies for a range of colors in the neutral polymer films, multi-colored electrochromism, and accessible states for reduction leading to n-type doping. The polymers prepared were characterized using cyclic voltammetry, colorimetry, and UV-Vis-NIR spectroscopy demonstrating that the polymers can undergo both p- and n-type doping and color changes in both redox states. QD Polymers, Macromolecules 380-388 Electrochemical polymerization Conducting polymer Low band gap polymer Electrochromism
32	Chemical Synthesis and Ionic Conductivity of Water-Soluble Rigid-Rod Polyelectrolyte Chen, Yun-Sheng 15 February 2001 (has links) Poly(p-phenylenebenzobisimidazole), PBI, is a rigid-rod polymer with a fully conjugated backbone having superior mechanical properties, thermo-oxi- dative and solvent stabilities. The stabilities cause processing difficulties and in terms limit its applications in critical technologies, such as conducting polymers, nonlinear optics, and solid polyelectrolytes. In this study, a chemical derivative of PBI, poly[1,7-dihydrobenzo[1,2- d:4,5-d¡¦]diimidazo-2,6-diyl[2-(2-sulfo)-p-phenylene]], sPBI, was synthesized by polycondensation reaction of 1,2,4,5-tetraaminobenzene tetrahydrochloride with 2-sulfoterephthalic acid in poly(phosphoric acid). Isolated sPBI was measured in 30oC methanesulfonic acid for an intrinsic viscosity as high as 10.5 dL/g. sPBI polymer was then reacted with 1,3-propanesultone in dimethylsulfoxide containing sodium hydride for water-soluble rigid-rod polyelectrolyte, poly[1,7- dipropylsulfobenzo-[1,2-d:4,5-d¡¦]diimidazo-2,6-diyl-[2,(2-sulfo)-p-phenylene]], sPBI-PS(Na+). sPBI-PS(Na+) was further converted to sPBI-PS(Li+) with hydrochloride and followed with lithium hydroxide. Various analyses were applied to ascertain chemical structure, purities and thermal properties of synthesized monomers and polymers. sPBI-PS(Li+) aqueous solutions were doped individually with lithium salts of LiI, LiBF4, and LiCF3SO3 at concentrations up to 1.7¡Ñ10-5 wt./wt., which were cast into freestanding films of 10-25 £gm in thickness. Direct-current conductivity measured at room- temperature parallel to the film surface was as large as 9.74¡Ñ10-5 S/cm. The ionic nature of the conductivity was revealed by constant-voltage depletion measurements. X-ray scattering results suggested that the cast film was in-plane isotropic but out-of-the plane anisotropic with the rigid-rod backbone lying in the plane of the film. Rid-rod polymer Ionic Conductivity Anisotropic X-ray Scattering Water-soluble Conducting Polymer Polycondensation Polyelectrolyte
33	Phase Structure of Alkylated Poly(ethylene-alt-maleic anhydride) and Poly(styrene-alt-maleic anhydride) HSU, SHU-HAO 12 June 2001 (has links) Thermal behavior and molecular packing of alkylated poly(ethylene- alt- maleic anhydride) and poly(styrene-alt-maleic anhydride) were studied by means of differential scanning calorimetry, thermogravimetry, polarizing optical microscopy, and X-ray diffraction. Effects of the length and graft density of alkyl side chains and backbone rigidity on the thermal behavior and on the structure of the mesophases are discussed. side chain crystallize smectic comb-like polymer layer structure conducting polymer surfactant
34	Electrochemical processing of polythiophene films with enhanced structural order Santoso, Handoko Tirto 18 August 2011 (has links) Intrinsically conducting polymers (ICPs) with high mechanical strength and electrical conductivity are attractive for several applications spanning the fields of energy, defense, and transportation. Electrochemically processed polythiophene (PTh) films are a class of ICPs that have been demonstrated recently to possess electrical conductivities as high as 1,300 S/cm and be stronger than common types of processed aluminum foils. While these results are promising, the electrical conductivity of PTh is still low compared to metals and the effects of important process conditions such as electrode resistance, distance between working and counter electrodes, and thiophene concentration on the structure and physical properties of electrochemically processed PTh films must be investigated in detail. In this work, electrode resistance and inter-electrode distance were demonstrated to be inversely proportional to the charge efficiency for PTh film growth. A critical concentration of thiophene that produced films with the highest conductivity was also revealed. Anionic surfactants sodium dodecyl sulfate (SDS) and sodium dodeclybenzene sulfonate (SDBS) were used, with and without a proton scavenger, in the Lewis acid boron trifluoride diethyl etherate (BFEE) electrolyte, which allows polymerization of thiophene at low oxidation potentials, to enhance the ordering and conjugation length of PTh through stabilization of the radical cation of thiophene via the dodecyl chain of the anionic surfactants. X-ray diffraction spectra revealed enhanced order and packing when surfactant was used during the processing of PTh films, and measured electrical conductivities were increased by as much as 300% because of the surfactant-mediated structural improvements. Necking behavior observed in tensile test of PTh films with anionic surfactant additives also suggests chain alignment and increased chain length. Molecular structure Anionic surfactant Conducting polymer Electrochemical polymerization Polythiophene Polythiophenes Conducting polymers
35	Synthesis and Characterization of Nanocomposites for Electrochemical Capacitors Alvi, Farah 01 January 2012 (has links) Presently there are deep concerns over the environmental consequences and the consumption of non-renewable energy sources, with the accelerated greenhouse effect, triggered enormous interest in the use of renewable energy sources e.g., solar, hydropower, wind and geothermal. However the intermittent nature of harvesting renewable energy sources has recently gained considerable attention in the alternative reliable, cost effective, and environmentally friendly energy storage devices. The supercapacitor and lithium ion batteries are considered more efficient electrical energy storage devices than conventional energy storage systems. Both devices have many useful and important applications; they could be an excellent source for high power and high energy density, especially in portable electronic devices and Electrical Vehicles (EVs) or Hybrid Electrical Vehicles (HEVs). In order to make the efficient usage of these stationary energy storage devices, state of the art research on new and advanced electrode materials is highly needed. The aim of this dissertation is to investigate the scope of graphene/metal oxide-conducting polymer nanocomposites electrodes for light weight, high power density and wider voltage window supercapacitor devices. The facile chemical polymerization approach was used to synthesize the aromatic and heterocyclic conducting polymer nanocomposites. For aromatic nanocomposites, several materials were synthesized includes ZnO-PANI, ZnO/G-PANI,RuO2-PANI and G-PANI. Subsequently these materials have been characterized by physical, structural techniques e.g Raman Spectroscopy, Fourier Transform Infrared Spectroscopy (FTIR), Xray-Diffraction (XRD), Scanning Electron Microscopy (SEM), and Transmission Electron Microscopy (TEM). In addition to material characterization the prepared material was also characterized by electrochemical measurements using cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), and chrono potentiometry for supercapacitor electrodes. Since graphene is a two-dimensional single-atom-thick sp2 hybridized carbon structure due to its extraordinary characteristic, high electrical conductivity, chemical stability and large theoretical surface area (over 2600 m2 g−1) has gained immense interest in the future generation of renewable energy devices. Therefore, among all aromatic based nanocomposites, the Graphene-Polyaniline (G-PANI) rendered promisingly high specific capacitance around 440 F/g with the excellent cyclic stability. The higher specific capacitance of G-PANI might be due to the high conductivity and superior electrochemical properties of graphene in G-PANI nanocomposites. However, besides the G-PANI, other aromatic nanocomposites e.g., RuO2-PANI, ZnO-PANI and G/ZnO-PANI also showed the potential of low cost and flexible supercapacitor electrodes with the reasonably good specific capacitance as 360 F/g, 300 F/g, and 275 F/g. We have further investigated the role of conductivity by adding different amount of graphene in G-PANI nanocomposites to optimize device performance with the specific capacitance and columbic efficiency of 440 F/g and 90% respectively.Further the other important parameters, relate with the electrode thickness, type of electrolytes, concentration of electrolytes and the effect of the solvent has also been studied to achieve the overall performance and reliability of the device. Moreover, in order to have the comprehensive study of conducting polymer besides the aromatic conducting polymer the heterocyclic polymers e.g., polythiophene and poly (3, 4-ethylenedioxythiophenes) (PEDOT) nanocomposites were studied at length to evaluate their role for the cost effective, large surface area and flexible green energy storage devices and has shown great prospects for commercial application. Therefore, G-Cps nanocomposites have proved to be a promising electrode material choice to facilitate the ionic diffusion and contact of the electrolytes to improve the specific capacitance and performance of the device. Columbic Conducting Polymer Efficiency Electrochemistry Graphene Supercapacitor American Studies Arts and Humanities Nanoscience and Nanotechnology Oil, Gas, and Energy
36	Phosphorescent cyclometalated iridium(III) complexes and corresponding conducting metallopolymers Hesterberg, Travis Wayne 06 July 2012 (has links) Conducting metallopolymers have been investigated for a variety of applications due to their ability to take advantage of both the mechanical processability of the polymer material, as well as the optical and electronic properties of the metal. Our project goal is to design, synthesize and characterize novel iridium(III)-containing conducting metallopolymers for use as the active layer in polymer light-emitting diodes. We have utilized thiophene functionalized ligands that can be readily electropolymerized into conducting polymer thin films and can be easily incorporated into a device structure. Iridium(III) was chosen as the metal center due to its promising photophysical properties, as similar complexes have demonstrated high luminescent quantum yields and short phosphorescent lifetimes. The coordination environment around the metal can be altered synthetically to tune the emission wavelength across the visible spectrum. The synthetic control over the polymer backbone, as well as the iridium(III) ligand environment, allowed us to independently vary each component, which has provided a variety of materials. The materials are characterized through 1H and 13C NMR, mass spectrometry, elemental analysis, electrochemistry, X-Ray diffraction and X-Ray Photoelectron Spectroscopy. The photophysical properties of the materials are studied through UVvii Visible absorption spectroscopy, UV-Vis-NIR spectroelectrochemistry and steadystate/ time-resolved emission spectroscopy. / text Polymer light emitting diodes PLED Iridium(III) complexes Iridium complexes Electropolymerization Metallopolymer Conducting polymer
37	Synthesis and electrochemical modulation of the actuator properties of poly(phenazine-2,3-diimino (pyrrol-2-yl)). Botha, Shanielle Veronique. January 2008 (has links) <p>The focus of this study is to synthesize a novel hinged polymer actuator. The linking molecule (hinge) is phenazine with interconnected dipyrrole units.</p> Conducting polymer Polypyrrole Phenazine Film thickness Controlled drug release.
38	Développement de modules thermoélectriques imprimés et flexibles pour des applications à température ambiante / Printed and flexible thermoelectric devices for room temperature applications Yvenou, Etienne 25 October 2017 (has links) L’effet thermoélectrique permet la conversion directe et réversible d’un flux de chaleur en courant électrique via l’utilisation de semi-conducteurs de type-p et de type n. Les polymères conjugués, comme le poly(3,4-éthylènedioxythiophène) (PEDOT) sont pressentis pour être des alternatives aux alliages de tellurure de bismuth (Bi2Te3) coûteux, toxiques et difficiles à synthétiser.Cette thèse se propose d’améliorer la conductivité électrique d’un PEDOT et de faciliter sa mise en œuvre par une technique d’impression grande surface comme le spray.La première partie porte sur l’amélioration de la synthèse par tournette du PEDOT : OTf dont le dopage est stabilisé par le contre-ion trifluorométhanesulfonate (OTf-). Plusieurs co-solvants sont testés comme la pyridine ou la NMP. Ces co-solvants permettent de ralentir la polymérisation et d’améliorer ainsi la structure du matériau. Des conductivités électriques de 3600 S.cm-1 avec un coefficient Seebeck aux environs de 20 µV.K-1 sont atteintes.La seconde partie étudie les avantages et les inconvénients d’une synthèse de ce PEDOT : OTf amélioré par spray ultrasonique. Cette technique permet de conserver la formulation développée pour le dépôt par tournette. Il est possible d’obtenir des films épais (~ 1 µm) avec une conductivité électrique supérieure à 1650 S.cm-1. Des études par diffraction des rayons X et de transports permettent de comparer les deux méthodes de dépôt et d’orienter les choix de formulation et de procédé.Finalement, avec ces améliorations apportées, des exemples de modules thermoélectriques imprimés sont présentés et évalués. Ainsi en imprimant plus de 300 thermocouples connectés en série puis roulés, un tel module thermoélectrique occupe une surface inférieure à une pièce de 50 centimes d’euro et peut générer 1 µW avec un gradient de température de 35 °C.Cette thèse souhaite pouvoir apporter des éléments de réponse sur la relation entre la mise en œuvre et les propriétés électriques des polymères conducteurs. / Thermoelectricity can convert directly and reversibly a heat flux into an electric current with p and n-type semiconductors. Conjugated polymers, such as poly(3,4-ethylenedioxithiophene) (PEDOT), offers an alternative to the best room temperature thermoelectric materials based on bismuth telluride alloys which used scarce, hazardous and hard to process raw materials.This PhD work aims to enhance the electrical conductivity of an in-situ polymerised PEDOT and make it easy to process with large scale printing techniques like spray-coating.The first part focus on the optimisation of this synthetized PEDOT through spin-coating. The doping of this PEDOT is stabilised with the counter-ion trifluoromethanesulfonate (OTf-). One way of enhancement is to add co-solvents like pyridine and NMP in order to slow down the polymerisation rate. Consequently, PEDOT:OTf get a better structure and reach an outstanding electrical conductivity of 3,600 S.cm-1 without decreased the Seebeck coefficient which remains around 20 µv.K-1.The second part studies pro and cons of the ultrasonic spray as a coating technic to this enhanced PEDOT:OTf. This technic allows to keep an ink formulation closed of the spin-coating one and can print thick films (~ 1 µm) with an electrical conductivity above 1650 S.cm-1. XRD and transport measurements are achieved in order to understand and compare both spray and spin-coating techniques. And therefore, to enlighten improvement on formulation and process.At last, several examples of spray-coated thermoelectric generators are shown and tested. Thus by printing more than 300 thermocouples connected in series and rolled into a cylinder, such devices could produce 1 µW with a gradient of temperature of 35 °C on a surface less than a 5 cm2 (size of a coin).This thesis work wishes to provide insight on the process-electrical relationship in conducting polymers. Polymère conducteur Procédé Thermoélectricité Electronique organique Conducting polymer Process Thermoelectricity Organic electronic 680
39	Synthesis and electrochemical modulation of the actuator properties of poly(phenazine-2,3-diimino (pyrrol-2-yl)) Botha, Shanielle Veronique January 2008 (has links) Magister Scientiae - MSc / The focus of this study is to synthesize a novel hinged polymer actuator. The linking molecule (hinge) is phenazine with interconnected dipyrrole units. / South Africa Conducting polymer Polypyrrole Phenazine Film thickness Controlled drug release
40	Estudo espectroeletroquímico de um copolímero alternado de PANI e PPS: PPSA-poli(sulfeto de fenileno-fenilenamina) / Study and spectroelectrochemical characterization of a derivative of poly(aniline) and poly(p-phenylene sulfide): Poly(phenylene sulfide - phenyleneamine) Fernanda Ferraz Camilo Bazito 05 July 2002 (has links) Os polímeros condutores intrínsecos são materiais isolantes ou semicondutores que, quando submetidos a um processo de dopagem, passam a apresentar condutividade próxima à metálica. Dentre os polímeros condutores sintetizados mais estudados está a poli(anilina), (PANI), que apesar de ter sido sintetizada pela primeira vez há aproximadamente 150 anos, continua sendo objeto de estudo de muitos grupos de pesquisa por todo o mundo até hoje. Apesar das características atrativas da PANI (facilidade de preparação e dopagem, estabilidade química e baixo custo), ela é categorizada como um material insolúvel e infusível em condições normais, o que dificulta sua processabilidade e aplicabilidade. Em vista dessas características indesejáveis, muitos derivados da PANI, tais como PANIs substituídas, copolímeros e blendas, são preparados em busca de novos materiais mais solúveis e processáveis. A obtenção do PPSA, um copolímero alternado da PANI e do PPS, mostrou-se atraente devido à possibilidade desse material poder apresentar as propriedades desejáveis de ambos os homopolímeros, juntamente com uma maior solubilidade. Nesta tese, apresentar-se-á a preparação desse polímero bem como sua respectiva caracterização espectroscópica e térmica e a determinação da massa molecular pela técnica de espalhamento de luz. Um estudo do comportamento eletroquímico por voltametria cíclica combinada com técnicas \"in situ\": espectroscopia Raman Ressonante, UV-Visível e por microbalança eletroquímica a cristal de quartzo também será mostrado. / The intrinsic conducting polymers are insulating or semi-conducting materials that show conductivities similar to metals when submitted to a doping process. Polyaniline (PANI), synthesized for the first time 150 years ago, is still the subject of research of many groups in the world, being one of the most studied conductive polymers. Besides its attractive properties (easy synthesise and doping, chemical stability and low cost), PANI is an insoluble and infusible material in normal conditions, what makes its processability and applicability very difficult. In order to overcome these difficulties, many PANI derivatives, such as substituted PANIs, copolymers and blends have been prepared, searching for more soluble materials and processible. PPSA, an alternate copolymer of PANI and PPS, is an attractive alternative because this material can show interesting properties of both homopolymers, together with a higher solubility. In this thesis it will be shown the preparation of this copolymer, as well as its spectroscopic and thermal characterization, and the determination of its molar mass by light scattering. The electrochemical behavior, studied by cyclic voltammetry combined with \"in situ\" techniques such as Raman resonant spectroscopy, UV-VIS and electrochemical quartz crystal microbalance, will also be shown. Copolímero Espectroeletroquimica Poli(sulfeto de fenileno) Polianilina Polímero Condutor Conducting polymer Copolymer Poly(phenylene sulfide) Polyaniline Spectroelectrochemistry

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