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31	POLYMER-MEDIATED ELECTROCHEMISTRY IN SOL-GEL THIN FILMS AND SPECTROELECTROCHEMICAL CHARACTERIZATION OF MOLECULAR ADLAYERS ON INDIUM-TIN OXIDE ELECTRODE SURFACES Doherty, Walter John January 2005 (has links) This research focuses on the development of spectroelectrochemical sensor formats based on thin film molecular architectures and electrochemical detection of sol-gel encapsulated macromolecular recognition elements. To achieve this goal, there were two major objectives: 1) to demonstrate and characterize conductive polymer grown electrochemically in porous sol-gel thin films with specific regard to the ability of the polymer to mediate charge transfer between sol-gel encapsulated molecules and the electrode surface, and 2) to develop a means to probe the spectroscopic properties of highly absorbent thin films as a function of applied potential. Toward the first objective, diffusion of a derivatized thiophene monomer into a sol-gel thin film and subsequent electropolymerization at an underlying indium-tin oxide (ITO) surface was found to produce a conductive network of polymer capable of mediating electron transfer from encapsulated redox centers in the bulk of the sol-gel film to the electrode surface. At high levels of polymer loading, emergent, sol-gel templated, polymeric structures are formed which extend from the sol-gel surface into the electrolyte solution and exhibit electrochemical properties of ultramicroelectrode arrays. To achieve the second objective, a polychromatic, electroactive attenuated total internal reflectance (EA-ATR) instrument was developed consisting of an indium-tin oxide (ITO) coated glass internal reflection element (IRE). In addition to a high degree of surface sensitivity relative to transmission geometries, this geometry affords acquisition of absorption anisotropy information, via polarization of the incident beam, to determine the orientation distribution in molecular adlayers. To demonstrate these abilities, the orientational distribution of monolayer and bilayer films of perylene and copper phthalocyanine derivatives, respectively, was determined. Furthermore, it was demonstrated that the EA-ATR could be used in a potential-modulated mode (PM-ATR) to study the kinetics of electro-optical switching in conductive copolymer thin films. spectroscopy electrochemistry conductive polymer molecular orientation sol-gel thin film
32	SIMULATING REMEDIATION OF TRICHLOROETHYLENE IN FRACTURED BEDROCK BY THERMAL CONDUCTIVE HEATING USING THE NUMERICAL MODEL TMVOC MCKENZIE, ASHLEY 07 January 2013 (has links) A thermal conductive heating (TCH) pilot test was conducted at the Naval Air Warfare Center (NAWC) in West Trenton, New Jersey in 2009 in collaboration with TerraTherm, Inc., the Naval Facilities Engineering Services Center and the United States Geological Survey. The NAWC site was historically used as a jet engine testing facility from the mid-1950s to the late 1990s. During this time, the subsurface was contaminated with trichloroethylene (TCE) which was a common solvent used at the facility. The pilot test consisted of 15 heater/extraction wells installed to a depth of 16.8 m in weathered mudstone and operated for 102 days. Rock core samples were taken pre- and post-remediation to measure the initial TCE concentrations and evaluate the effect the TCH pilot test had. The data collected during the pilot test was used to create a two-dimensional (2D) finite difference model using TMVOC. TMVOC is part of the TOUGH 2 family of codes and is a numerical model that is capable of simulating multiphase flow, heat transfer and transport of volatile organic compounds in three-dimensional heterogenous porous media or fractured rock. The 2D model was used as a screening model to investigate TCE removal from the rock matrix when heating for 100 days with a similar heating pattern to what was employed at the NAWC site. The numerical domain incorporated three primary fractures with competent bedrock in between. As the test pilot was conducted in the weathered bedrock zone, a sensitivity analysis was first completed on the matrix permeability to help to match the TCE removal from the pilot test. The pilot test had a 63.5% removal of TCE from the study area compared to 67% from the baseline model. A limited sensitivity analysis was completed which investigated how the matrix porosity and rate of energy application would have on the success of TCE removal from the rock matrix. It revealed that the TCE removal increases with increased matrix porosity and increased rate of energy application. / Thesis (Master, Civil Engineering) -- Queen's University, 2013-01-02 22:32:05.274 trichloroethylene remediation fractured bedrock numerical model thermal conductive heating
33	Emerging Materials for Transparent Conductive Electrodes and Their Applications in Photovoltaics Zhu, Zhaozhao, Zhu, Zhaozhao January 2017 (has links) Clean and affordable energy, especially solar energy, is becoming more and more important as our annual total energy consumption keeps rising. However, to make solar energy more affordable and accessible, the cost for fabrication, transportation and assembly of all components need to be reduced. As a crucial component for solar cells, transparent conductive electrode (TCE) can determine the cost and performance. A light weight, easy-to-fabricate and cost-effective new generation TCE is thus needed. While indium-doped tin oxide (ITO) has been the most widely used material for commercial applications as TCEs, its cost has gone up due to the limited global supply of indium. This is not only due to the scarcity of the element itself, but also the massive production of various opto-electronic devices such as TVs, smartphones and tablets. In order to reduce the cost for fabricating large area solar cells, substitute materials for ITO should be developed. These materials should have similar optical transmittance in the visible wavelength range, as well as similar electrical conductivity (sheet resistance) to ITO. This work starts with synthesizing ITO-replacing nano-materials, such as copper nanowires (CuNWs), derivative zinc oxide (ZnO) thin films, reduced graphene oxide (rGO) and so on. Further, we applied various deposition techniques, including spin-coating, spray-coating, Mayer-rod coating, filtration and transferring, to coat transparent substrates with these materials in order to fabricate TCEs. We characterize these materials and analyze their electrical/optical properties as TCEs. Additionally, these fabricated single-material-based TCEs were tested in various lab conditions, and their shortcomings (instability, rigidity, etc.) were highlighted. In order to address these issues, we hybridized the different materials to combine their strengths and compared the properties to single-material based TCEs. The multiple hybridized TCEs have comparable optical/electrical metrics to ITO. The doped-ZnO TCEs exhibit high optical transmittance over 90% in the visible range and low sheet resistance under 200Ω/sq. For CuNW-based composite electrodes, ~ 85% optical transmittance and ~ 25Ω/sq were observed. Meanwhile, the hybridization of materials adds additional features such as flexibility or resistance to corrosion. Finally, as a proof of concept, the CuNW-based composite TCEs were tested in dye-sensitized solar cells (DSSCs), showing similar performance to ITO based samples. nano-materials nanowire solar cells transparent conductive electrodes metal oxide
34	Síntese e caracterização de membrana condutiva para tratamento de água e efluentes. / Synthesis and characterization of conductive membrane for water and waste water treatment. Piaia, Alessandra 29 August 2017 (has links) Neste trabalho, foram adicionadas diferentes concentrações de polianilina (PANI) a uma solução polimérica de poliétersulfona (PES) e N-metil-pirrolidona (NMP), com o intuito de sintetizar membranas de ultrafiltração a partir do método de inversão de fases. O desafio consistem em combinar alta condutividade elétrica, boas propriedades mecânicas e oxidação eletroquímica, permitindo assim que a oxidação de possíveis contaminantes ocorra ao mesmo tempo em que a membrana atua como uma barreira de filtração seletiva. O efeito da adição de PANI foi avaliado quanto à morfologia da membrana, capacidade de separação e desempenho, em termos de permeabilidade e condutividade. As membranas modificadas apresentaram uma morfologia muito singular quando analisadas pelo Microscópio Eletrônico de Varredura (MEV), poros maiores foram identificados, ausência da camada seletiva, diminuição da camada inferior e grandes fases aglomeradas ao longo da seção transversal. Devido ao aumento do tamanho dos poros, a seletividade das membranas modificadas foi comprometida. Os resultados de porosidade para as membranas modificadas variaram entre 53 e 66%. A permeabilidade e a condutividade das membranas modificadas aumentaram à medida que a concentração de PANI também aumentou. O fluxo mediano obtido para a membrana com concentração de 40% de PANI foi de 835 L.m-2.h-1, cerca de 5 vezes maior do que o fluxo mediano obtido para a membrana controle. Já a condutividade mediana obtida para a mesma membrana modificada foi de 1,7x10-6 S, cerca de 15 vezes maior do que a membrana controle. Durante o teste de voltametria cíclica não foram observadas reações de oxidação-redução, nem da solução de ferro-cianeto nem da própria polianilina, ao aplicar uma tensão variando entre -0,2 V e 0,8 V. Desta forma, a partir dos resultados, pode-se afirmar que a adição de Polianilina alterou a morfologia e o desempenho das membranas modificadas, destacando o incremento na permeabilidade, hidrofilicidade e condutividade, mantendo sua característica de ser uma barreira de filtração seletiva. / In this work, different concentrations of Polyaniline (PANI) were added to a polymer solution made of Polyethersulfone (PES) and N-methylpyrrolidone (NMP), in order to synthesize ultrafiltration membranes by the phase inversion method and the challenge of combine high electrical conductivity, good mechanical properties and electrochemical oxidation, thus allowing the oxidation of matter to occur at the same time that the membrane acts as a selective and reliable filtration barrier. The effect of PANI addition was evaluated regarding the membrane morphology, separation capacity and performance in terms of permeability and conductivity. The modified membranes presented a very unique morphology when analyzed by the Scanning Electron Microscope (SEM), larger pores were identified, absence of the selective layer, decrease of the lower layer and large agglomerated phases with phase contour characterization along the cross section. Due to the increase in pore size, the selectivity of the modified membranes was compromised. The porosity results for the modified membranes are only reflections of the morphology obtained, and the median porosities varied between 53 and 66%. The permeability and conductivity of the modified membranes increased as the PANI concentration also increased. The median flow obtained for the membrane with 40% PANI concentration was 835 L.m-2.h-1, about 5 times higher than the median flow obtained for the control membrane. The median conductivity obtained for the same modified membrane was 1.7x10-6 S, about 15 times higher than the control membrane. During the cyclic voltammetry test, no oxidation-reduction reactions were observed, neither the iron-cyanide solution nor the polyaniline itself, when applying a voltage ranging from -0.2 V to 0.8 V. From the results, it can be affirmed that the addition of polyaniline particles altered the morphology and performance of the modified membranes, highlighting the increase in permeability, hydrophilicity and conductivity, maintaining its characteristics of being a selective filtration barrier. Conductive membrane Efluentes (Tratamento) Performance Polyaniline Polyethersulfone Tratamento de água
35	Advances on the pyroresistive behaviour of conductive polymer composite Asare, Eric Kwame Anokye January 2017 (has links) The positive temperature coefficient (PTC) effect in conductive polymer composites (CPC) are still poorly understood with the thermal expansion of the polymer matrix accepted as the main cause. This thesis aims to study a model system able to explain the effect of the filler size and shape on the PTC behaviour of CPCs. Silver coated glass spheres and flakes are used as conductive fillers due to the ease in controlling uniform size and shape. In a controlled system it was demonstrated that the PTC intensity increases with increasing filler size and with decreasing filler content, both for conductive fillers. Combinations of different conductive fillers were investigated to explore the possibility to obtain both low percolation thresholds and high PTC intensities. Model systems in which at least one of the two conductive fillers is of relatively homogenous size and shape were used to facilitate unravelling some of the complicated relationships between (mixed) conductive fillers and the PTC effect. The PTC intensity of mixed fillers composites were dominated by the filler with the lowest PTC intensity, even at very low volume fractions. The PTC intensity was not only influenced by the conductive particle size but also by its size distribution. The effect of difference in linear coefficient of thermal expansion (CTE) of conductive fillers and polymer matrix based on a change in filler core on PTC behaviour was investigated. Damage to the particles due to the poor adhesion between the silver coating and the PMMA bead lead to the composite behaving like mixed filler composite. Hybrid polymers filled with silver coated glass flakes was also examined in order to enhance the PTC intensity. The PTC intensity of the composite increased with increasing PPE content but the negative temperature coefficient (NTC) effect was observed in all the composites.
36	Construção de biossensores utilizando polímeros condutores eletrônicos / Construction of biosensors using electronic conductive polymers Pablo Alejandro Fiorito 27 July 2001 (has links) Neste trabalho são elaborados biossensores para a detecção amperométrica de glicose. Para isso, imobilizou-se a enzima glicose oxidase em matrizes de polímeros condutores. Foram construídos sensores utilizando-se poli(pirrol) e poli(N-metilpirrol). Com o objetivo de substituir o oxigênio molecular na etapa de transdução do sinal, o ferroceno foi incorporado dentro do polímero condutor. Para isso, os polímeros foram elaborados utilizando misturas água-etanol como meio de polimerização. A inclusão do ferroceno no sensor resulta em maior sensibilidad à glicose (4,33 µA Mm-1 cm-2 para o biossensor preparado a partir da mistura água-etanol contendo o ferroceno e de 0,23 µA mM-1 cm-2 para o sensor sem ferroceno ). Por outro lado, permite o funcionamento do sensor a potenciais menores que no caso do sensor sem ferroceno (0,4 V para o sensor com ferroceno vs. 0,65 V para o caso sem ferroceno). O deslocamento do potencial de detecção para valores menos positivos não foi suficiente para evitar as interferências causadas pelos íons ascorbato e ureato. Para isto, mostrou-se 100% efetivo o recobrimento dos sensores com uma película de Nafion®. A sobreoxidação do poli(pirrol) também mostrou potencialidade para a eliminação de interferentes, embora o processo resulte na perda de sensibilidade, provavelmente causada pela desnaturação da enzima. Quando usado o poli(N-metilpirrol) como suporte para a enzima, obtiveram se melhores respostas, causadas pela possibilidade de se preparar filmes mais espessos, consequentemente de imobilizar maior quantidade de enzima, sem observar perda de resposta causada por problemas difusionais. / The present work describes the elaboration of a biosensor for glucose detection. The enzyme, glucose oxidase, was immobilized in different conducting polymers. Two different polymers were used: polypyrrole and poly(N-methilpyrrole ). With the aim of replacing the molecular oxygen in the transduction step, ferrocene has been immobilized within the conducting polymer. Once the ferrocenium was insoluble in water, in order to develop a different route, the electropolymerization was carried out in a mixture of water and ethanol (1:1). This procedure leads to a polymer with a poor electroactivity, detected by Raman experiments. The ferrocene addition in the sensor increases the sensitivity to the glucose determination (4,33 µA mM-1 cm-2 for the biosensor with ferroecene and 0,23 µA mM-1 cm-2 for the sensor without ferrocene). Alternatively, the sensor containing ferrocene allows to operate at less positive potentials than that one without ferrocene (+ 0,40 V and + 0,65 V, respectively). This potential shift was not enough to inhibit the interference caused by ascorbate and ureate ions. One method to avoid the interference problem was to recover the sensor with a very thin layer of Nafion. Also poly(pyrrole) overoxidation is a very efficient method to eliminate this interference, but this process leads to a sensitivity decrease dueto enzyme denaturation. A better response was observed for sensor assembled using the poly(Nmethyl-pyrrole) as the support for enzyme immobilization. This behavior was provoked by the thicker of polymer film formed leading to higher amount of immobilized enzyme. Even though, no diminution in the response was caused by diffusion problems. Biossensores Eletroquímica Polímeros condutores Biosensors Conductive polymers Electrochemistry
37	Análise fotocondutiva de estruturas fotovoltaicas baseadas em TiO2 e poli(3-hexiltiofeno) / Photoconductivity analysis of photovoltaic structures based on TiO2 and poly(3-hexylthiophene) Souza, Carlos Eduardo Zanetti de 21 December 2009 (has links) Neste trabalho investigamos o transporte eletrônico em dispositivos com estrutura ITO(óxido de estanho dopado com índio)/TiO2(dióxido de titânio)/RRP3HT(poli(3-hexiltiofeno)-regiorregular)/Al através de medidas de resposta espectral de fotocorrente, iluminando os dispositivos ora pelo eletrodo de ITO ora pelo de alumínio. O polímero RRP3HT é um politiofeno regiorregular e exibe uma atividade fotovoltaica relativamente alta. Os filmes de TiO2 e RRP3HT foram obtidos por spin-coating, sendo o óxido depositado a partir de uma dispersão coloidal de nanopartículas e o polímero a partir de uma solução de clorofórmio. O eletrodo de Al foi evaporado termicamente sobre o filme de polímero. As medidas de fotocorrente foram realizadas com o uso de uma lâmpada de Xe de 450W e de um monocromador e, depois de diversas medidas tendo a temperatura e a voltagem aplicada como parâmetros, obtivemos uma grande quantidade de importantes dados elétricos sobre os dispositivos. Dependendo das condições experimentais observamos diferentes respostas de fotocorrente: simbática ou antibática. Um modelo baseado em mecanismos de recombinação e na fotogeração de cargas, incluindo o perfil de absorção do RRP3HT, permitiu a obtenção de parâmetros elétricos importante em aplicações desse polímero a dispositivos fotodetectores e células solares. / In this work we investigated electronic transport phenomena in an ITO/TiO2/RRP3HT/Al structure using photoconductivity spectral response when devices were illuminated either by the ITO electrode or by the aluminum. RRP3HT is the regioregular poly(3-hexylthiophene), a polymer that exhibits a relatively strong photovoltaic activity. RRP3HT were dissolved in a solution of chloroform and nanoparticles of TiO2 were used in a colloidal dispersion. Both thin films of TiO2 and P3HT were deposited by spin coating technique over a commercial glass covered with ITO, and Al electrode was vacuum evaporated. Photoconductivity measurements were carried out making use of a Xenon lamp of 450 W and a monochromator to produce a single spectral line. After several measurements, having temperature and constant applied voltage as parameters, we obtained a great amount of important electrical data for the devices. Depending on the experimental conditions we obtained different photocurrent response, i. e. symbatic or antibatic. A model based on recombination mechanisms and photogenerated charges, including the absorption profile of the RRP3HT, allowed us to get some electrical parameters that are important for photovoltaic and photoconductive applications. Conductive Polymers Dispositivos Orgânicos Fotocondução Organic Devices Photoconduction Polímeros Condutores
38	Probing electrical and mechanical properties of nanoscale materials using atomic force microscopy Rupasinghe, R-A- Thilini Perera 01 December 2015 (has links) Studying physical properties of nanoscale materials has gained a significant attention owing to their applications in the fields such as electronics, medicine, pharmaceutical industry, and materials science. However, owing to size constraints, number of techniques that measures physical properties of materials at nanoscale with a high accuracy and sensitivity is limited. In this context, development of atomic force microscopy (AFM) based techniques to measure physical properties of nanomaterials has led to significant advancements across the disciplines including chemistry, engineering, biology, material science and physics. AFM has recently been utilized in the quantification of physical-chemical properties such as electrical, mechanical, magnetic, electrochemical, binding interaction and morphology, which are enormously important in establishing structure-property relationship. The overarching objective of the investigations discussed here is to gain quantitative insights into the factors that control electrical and mechanical properties of nano-dimensional organic materials and thereby, potentially, establishing reliable structure-property relationships particularly for organic molecular solids which has not been explored enough. Such understanding is important in developing novel materials with controllable properties for molecular level device fabrication, material science applications and pharmaceutical materials with desirable mechanical stability. First, we have studied electrical properties of novel silver based organic complex in which, the directionality of coordination bonding in the context of crystal engineering has been used to achieve materials with structurally and electrically favorable arrangement of molecules for an enhanced electrical conductivity. This system have exhibited an exceptionally high conductivity compared to other silver based organic complexes available in literature. Further, an enhancement in conductivity was also observed herein, upon photodimerization and the development of such materials are important in nanoelecrtonics. Next, mechanical properties of a wide variety of nanocrystals is discussed here. In particular, an inverse correlation between the Young’s modulus and atomic/molecular polarizability has been demonstrated for members of a series of macro- and nano-dimensional organic cocrystals composed of either resorcinol (res) or 4,6-di-X-res (X = Cl, Br, I) (as the template) and trans-1,2-bis(4-pyridyl)ethylene (4,4’-bpe) where cocrystals with highly-polarizable atoms result in softer solids. Moreover, similar correlation has been observed with a series of salicylic acid based cocrystals wherein, the cocrystal former was systematically modified. In order to understand the effect of preparation method towards the mechanical properties of nanocrystalline materials, herein we have studied mechanical properties of single component and two component nanocrystals. Similar mechanical properties have been observed with crystals despite their preparation methods. Furthermore, size dependent mechanical properties of active pharmaceutical ingredient, aspirin, has also been studied here. According to results reduction in size (from millimetre to nanometer) results in crystals that are approximately four fold softer. Overall, work discussed here highlights the versatility of AFM as a reliable technique in the electrical, mechanical, and dimensional characterization of nanoscale materials with a high precision and thereby, gaining further understanding on factors that controls these processes at nanoscale. Atomic Force Microscopy Conductive Probe AFM Nanoindentation Nanomaterials Chemistry
39	Synthetic strategies for denatured cytochrome-c analogues towards analytical reporting of NOx species Farao, Al Cerillio January 2019 (has links) Philosophiae Doctor - PhD / Nitric oxide (NO) plays a key role as biological messenger in the biological system, however detection and quantification thereof has always posed significant problems. NOx is a principal constituent of air pollutants. There are seven oxides of nitrogen of which N2O, NO and NO2 are most important. NO is a free radical and reacts extremely fast with oxygen, peroxides and superoxides. It’s these reactions which are responsible for NO’s fleeting existence. The specific detection and quantification of NO still remains challenging. Most techniques rely on the measurements of secondary nitrite and nitrate species. Electrochemical techniques using ultra micro-electrode systems presented the possibility of direct detection of NO, offering a range of favourable characteristics; good selectivity towards NO, good sensitivity, fast response, long-term stability and ease of handling. Electrochemical detection of NO relies on the modification of electrode surfaces and exploiting the redox properties of NO. NO can either be oxidized or reduced electrochemically depending on the nature of the solution. Under cathodic current NO is reduced to nitrosyl, a highly unstable derivative of NO. These nitrosyls are subject to a serious of chemical reactions to eventually form nitrous oxide. Due to the interferences presented by the electrochemical reduction of NO, the electro oxidation of NO is therefore the methodology of choice for NO detection. The electrochemical oxidation of NO occurs at positive potentials around 800 mV vs. Ag/AgCl. However this potential range is not only favourable to NO oxidation but can lead to the oxidation of several other biological species. These interfering species are biologically present at concentrations higher than NO therefore selectivity is of the highest order when designing these electrode systems. Some nitric oxide sensors are limited in their sensitivity, stability and reproducibility. Direct electron transfer between redox proteins and conductive membrane layers has been scrutinized for years in an attempt to reproduce the mechanistic charge transfer processes for sensor application. However, literature reports have presented many arguments on the complexities associated with depositing these enzymes on electrode surfaces for the purpose of reproducing direct electron transfer at metalloprotein centres. The study sets out to design a material which could mimic the electrochemistry of denatured cytochrome-c. To achieve this it was imperative to design a polymer which could reproduce the electrochemistry of the ligands coordinated to the metal centre of the metalloprotein. A novel Schiff base was synthesized by cross-linking naphthalene to pyrrole to produce the monomer, N,N-bis((1H-pyrrol-2-yl)methylene)naphthalene-2,3-diamine). The monomer was electrodeposited on a screen print carbon electrode (SPCE) vs. Ag/AgCl and served as a supporting layer for denatured cytochrome-c. Cytochrome-c is classified as a metalloprotein. These metalloproteins possess metal centres which when denatured unfolds and allows access to the metal centre. Cytochrome-c was subjected to thermal denaturation which opened up the iron centre. The denatured metalloprotein was cross-linked to the ligand to reconstruct the heme centre environment. This was believed to facilitate the electrochemical activity of the system and allow for electrochemical analysis of these metalloproteins for sensor application. The redox behaviour of the sensors were modelled in phosphate buffer solution (PBS) with cyclic voltammetry. Electrochemical analysis reported the sensors to possess reversible electrochemistry with diffusion control characteristics. The sensor recorded a redox system in the negative potentials range. Following the establishment of the electrochemical profile of the sensor an attempt was made to produce a synthetic analogue of denatured cytochrome-c. Iron (II) was chelated to the monomer N,N-bis((1H-pyrrol-2-yl)methylene)naphthalene-2,3-diamine) to form an iron ligand complex. The complex was subjected to a series of characterization techniques which confirmed coordination to the metal centre. The iron ligand complex was electrodeposited on a SPCE over the potential window of -1 V and 1 V to model the electrochemical behaviour of the sensor. The material was found to be electroactive. Subsequent electrochemical analysis revealed the system to have electrochemical properties, analogous to that of the denatured cytochrome-c system. The sensor was applied in NO and NO2 studies and displayed an affinity towards NO. Based on extrapolated values it was postulated that the lower limit range for NO detection was in the range of 30 to 40 nM. The potentials recorded were lower than the reported oxidation potentials for nitric oxide. The sensor displayed stability and selectivity towards nitric oxide within a complex matrix. The complex matrix employed in this study was synthetic urine that was synthesised in the lab. The sensor displayed the capacity for linear range of NO detection with very low error margins. / 2021-09-01 Conductive polymers Cyclic voltammetry Diffusion coefficient Electrochemistry Imine
40	Fabrication, Modelling and Application of Conductive Polymer Composites Price, Aaron David 19 December 2012 (has links) Electroactive polymers (EAP) are an emerging branch of smart materials that possess the capability to change shape in the presence of an electric field. Opportunities for the advancement of knowledge were identified in the branch of EAP consisting of inherently electrically conductive polymers. This dissertation explores methods by which the unique properties of composite materials having conductive polymers as a constituent may be exploited. Chapter 3 describes the blending of polyaniline with conventional thermoplastics. Processing these polyblends into foams yielded a porous conductive material. The effect of blend composition and processing parameters on the resulting porous morphology and electrical conductivity was investigated. These findings represent the first systematic study of porous conductive polymer blends. In Chapter 4, multilayer electroactive polymer actuators consisting of polypyrrole films electropolymerized on a passive polymer membrane core were harnessed as actuators. The membrane is vital in the transport of ionic species and largely dictates the stiffness of the layered configuration. The impact of the mechanical properties of the membrane on the actuation response of polypyrrole-based trilayer bending actuators was investigated. Candidate materials with distinct morphologies were identified and their mechanical properties were evaluated. These results indicated that polyvinylidene difluoride membranes were superior to the other candidates. An electrochemical synthesis procedure was proposed, and the design of a novel polymerization vessel was reported. These facilities were utilized to prepare actuators under a variety of synthesis conditions to investigate the impact of conductive polymer morphology on the electromechanical response. Characterization techniques were implemented to quantitatively assess physical and electrochemical properties of the layered composite. Chapter 5 proposes a new unified multiphysics model that captures the electroactive actuation response inherent to conductive polymer trilayer actuators. The main contribution of this investigation was the proposal and development of a new hybrid model that unifies concepts from charge transport and electrochemomechanical models. The output of the proposed model was compared with published data and shown to be accurate to within 10%. Finally, Chapter 6 demonstrated the application of these materials for use as precision mirror positioners in adaptive optical systems. Conductive polymers Polypyrrole Electroactive polymers Polyaniline 0548 0794

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