Global ETD Search

141	Synthèse d'un copolymère ionique électrochimiquement actif à base de ferrocène-imidazolium et son utilisation possible en matériaux composites Skrypnik, Valentyn 09 1900 (has links) No description available. Polymère ionique électroactif Électrochimie Matériaux composites Graphite exfolié Pseudocapacité Supercapaciteurs Redox-active ionic polymer Electrochemistry Composite material Carbon-based materials properties Pseudocapacitance Supercapacitors
142	Synthesis of anisotropic plate-like nanostructures using gibbsite nanoplates as the template Cao, Jie 21 April 2017 (has links) In der vorgelegten Arbeit werden sowohl effiziente als auch einfache Modifikationsansätze zur funktionalen Polymerumhüllung von Gibbsit-Plättchen präsentiert. Die plättchen-förmige Morphologie bleibt dabei nach der Polymerumhüllung erhalten. Im ersten Teil wird ein einfacher Ansatz zur Synthese von anisotropen, plättchen-förmigen Gibbsit-Polydopamin (G-PDA) Partikeln vorgestellt. Au NPs von kontrollierbarer Größe wurden auf der G-PDA Partikeloberfläche gebildet. Diese zeigten katalytische Aktivität zur Reduktion von 4-Nitrophenol und Rhodamin B (RhB) mittels Borhydrid. Die Partikel können durch ihre große, plättchen-förmige Kontaktfläche und der stark adhäsiven Eigenschaften der PDA Hülle einfach mittels Spin-Coating auf Siliziumsubstrate aufgebracht werden. Der so präparierte Nanokatalysator kann nun einfach wiederaufbereitet werden und zeigt hervorragende Wiederverwendbarkeit. Im zweiten Teil wurden anisotrope, hybride Kern-Schale Mikrogele mit wohldefinierter Struktur synthetisiert. Dabei bilden die Gibbsit Nanoplättchen den Kern und vernetztes, thermosensitives Poly(N-isopropylacylamid) die Hülle. Depolarisierte dynamische Lichtstreuung zeigte, dass die hybriden Mikrogele im kollabierten Zustand durch die plättchen-förmigen Kerne eine anisotrope Form annehmen. Der dritte Teil der Arbeit befasst sich mit der Herstellung von hochdispergierbaren, mesoporösen und stickstoffhaltighohle Kohlenstoff-Nanoplättchen. Diese neuartige Kohlenstoff-Nanostruktur wurde mittels sogenannter Silika-Nanocasting Technik unter Veswendung von hexagonalen Gibbsit-Templat und Dopamin als Kohlenstoffquelle synthetisiert. Solche hohlen Kohlenstoff-Nanostrukturen weisen exzellente, kolloidale Stabilität in wässrigen Medien vor und können direkt als Elektrodenmaterial für Superkondensatoren verwendet werden. Außerdem können sie in polyionischen Flüssigkeiten hohe Kapazitäten erzielen, wobei gleichzeitig eine hervorragende elektrochemische Stabilität gewährleistet wird. / In the present thesis, efficient and simple modification approaches have been developed to coat gibbsite platelets with a controllable thickness of functional polymer shell, which preserves the plate-like morphology after the polymer coating. In the first part, a facile approach has been presented for the synthesis of anisotropic plate-like gibbsite-polydopamine (G-PDA) particles. Au NPs with tunable size have been formed on the G-PDA particle surface, which show efficient catalytic activity for the reduction of 4-nitrophenol and Rodamine B (RhB) in the presence of borohydride. Such nanocatalysts can be easily deposited on silicon substrate by spin coating due to the large contact area of the plate-like G-PDA particles and the strong adhesive behavior of the PDA layer. The substrate-deposited nanocatalyst can be easily recycled, which shows excellent reusability. Secondly, anisotropic hybrid core-shell microgels with well-defined structures have been synthesized using gibbsite nanoplate as core and crosslinked thermosensitive poly(N-isopropylacrylamide) as shell. The analysis by depolarized dynamic light scattering shows that the hybrid microgels have an anisotropic shape in the collapsed state, caused by the anisotropy of the plate-like core. In the third part, highly dispersible mesoporous nitrogen-doped hollow carbon nanoplates have been synthesized as a new carbon nanostructure via silica nanocasting technique using dopamine as carbon precursor and hexagonal-shaped gibbsite as template. Such hollow carbon nanoplates show excellent colloidal stability in aqueous media and can be directly applied as electrode materials in supercapacitors, which offer high capacitance and excellent electrochemical stability when using poly(ionic liquid) nanoparticles as binder. Polydopamin Gibbsit-Plättchen Katalysator hybrides Mikrogel hohle Kohlenstoff Nanoplättchen Superkondensator. polydopamine gibbsite platelets catalysts hybrid microgels hollow carbon nanoplates supercapacitors. 540 Chemie 30 Chemie VE 8007 VE 9857 ddc:540
143	Electrodes pour supercondensateurs à base d’oxydes de cobalt conducteurs / Supercapacitor electrodes based on conductive cobalt oxides Godillot, Gérôme 16 October 2012 (has links) Les travaux de recherche actuels menés dans le domaine des supercondensateurs s’orientent vers l’augmentation des densités d’énergie, notamment via le développement de supercondensateurs hybrides "oxydes de métaux de transition / carbones activés". Dans ce contexte, les présents travaux avaient pour objectif d’évaluer les propriétés d’oxydes de cobalt nanométriques en tant que matériaux d’électrode positive pour supercondensateur hybride.Ces oxydes de cobalt, de structure spinelle, sont préparés par précipitation de nitrate de cobalt en milieu basique (T < 90 °C). Ils possèdent une formule chimique du type HxLiyCo3-δO4•zH2O et présentent une bonne conductivité électronique grâce à la présence d’ions H+, Li+ et Co4+. Les analyses par DRX, ATG, RMN et les mesures de conductivité électroniques ont mis en évidence une réorganisation de la structure spinelle de ces matériaux sous l’effet d’un traitement thermique, conduisant à une augmentation du rapport Co4+/Co3+ ainsi qu’à une amélioration des propriétés de transport électrique. L’association d’une conductivité électronique élevée et d’une forte surface spécifique confère à ces oxydes des performances prometteuses en tant que matériaux d’électrode.L’étude des propriétés électrochimiques a montré la présence de deux modes de stockage des charges, l’un électrostatique (double couche électrochimique) et l’autre faradique via l’oxydation et la réduction du cobalt. Elle a également permis de déterminer la signature électrochimique de ces oxydes (capacité, fenêtre de potentiels), prérequis indispensable à leur intégration dans une cellule complète. Finalement, un supercondensateur hybride "oxyde de cobalt / carbone activé" a été assemblé et équilibré, donnant lieu à des performances attractives (61,6 F/g sur 1,60 V). / Investigations on supercapacitors are focusing on increasing energy densities, in particular with the development of hybrid supercapacitors "metal oxides / activated carbons". In this field, the present work aims at evaluating nanometric cobalt oxides as positive electrode material for hybrid supercapacitors.These oxides, with spinel structure, are synthesized by precipitation of cobalt nitrate in a basic medium (T < 90 °C). They exhibit formulae such as HxLiyCo3-δO4•zH2O and good electronic properties thanks to the presence of H+, Li+ and Co4+ ions. XRD, TGA, NMR analysis as well as electronic measurements have highlighted a structural reorganization of the spinel structure under thermal treatment, resulting in increase of the Co4+/Co3+ ratio and an enhancement of the electronic transport properties. The high electronic conductivity together with a huge specific surface area imparts these oxides promising performances as electrode material.The study of the electrochemical properties underlines two charge storage mechanisms, one electrostatic (electrochemical double layer) and the other one faradic through the oxidation and the reduction of cobalt. The electrochemical signature (capacity, potential window) of these oxides was also determined in order to develop a complete cell. Finally, a hybrid supercapacitor "cobalt oxide / activated carbon" was assembled and balanced, revealing attractive performances (61,6 F/g over 1,60 V). Supercondensateurs hybrides Matériau d’électrode Nanomatériau Oxyde de cobalt Spinelle Co3O4 Diffraction des rayons X RMN du 7Li et du 1H Conductivité électronique Hybrid supercapacitors Electrode material Nanomaterial Cobalt oxide Spinel Co3O4 X-ray diffraction 7Li and 1H NMR Electronic properties 621.312 42
144	Oxydes de manganèse et ses composites à base de nanotubes de carbone ou de graphène pour la réalisation de supercondensateurs / Manganese oxides and its composites made of carbon nanotubes or graphene for the realization of supercapacitors Mery, Adrien 19 October 2016 (has links) Les travaux réalisés dans cette thèse ont porté sur la synthèse d’oxydes de manganèse et leur association dans des composites avec des matériaux carbonés (NTC, Graphène), pour une utilisation comme matériaux d’électrodes de supercondensateurs fonctionnant en milieux aqueux. Les caractérisations physico-chimiques et électrochimiques ont été menées sur ces matériaux afin d’évaluer leurs performances et étudier l’effet de la nanostructuration. Il s’est avéré que la réalisation de nanocomposites MnO2/ nanotubes de carbone ou MnO2/ oxydes de graphène réduits contribue à l’amélioration des performances électrochimiques. Plusieurs compositions Mn/C ont été étudiées afin de réaliser un matériau d’électrode de supercondensateur optimisé. Des dispositifs asymétriques en milieux aqueux ont été assemblés associant les meilleurs nanocomposites avec une électrode négative de graphène. De nettes améliorations en termes de densités d’énergie et de puissance ont été obtenues sur ces systèmes asymétriques fonctionnant sur 2 volts en milieux aqueux. / The work realized in this thesis focused on the synthesis of manganese oxides and their assembly in composites with carbon materials (CNT, graphene) for supercapacitor applications in aqueous media. Physico-chemical and electrochemical characterizations were conducted to evaluate the effect of the nanostruturation. It was found that nanocomposites MnO2/CNT and MnO2/ reduced graphene oxide contributed to improve the electrochemical performances in aqueous media. Several compositions Mn/C were tested to estimate the best ratio for optimized electrode materials. In order to maximize the energy of the devices, asymmetric devices in aqueous media were assembled using graphene as negative electrode and nanocomposites for positive. Clear improvements in term of energy and power densities were obtained with these systems working at 2 volts in aqueous media. Stockage d’énergie Supercondensateurs Dispositifs asymétriques Matériaux d’électrodes Oxydes de graphène réduits Nanotubes de carbone Oxydes de manganèse Composites Milieu aqueux Energy storage Supercapacitors Asymmetric systems Electrode materials Reduced graphene oxide Carbon nanotubes Manganese oxides Composite Aqueous media
145	Solid-state NMR and Electrochemical Dilatometry Study of Charge Storage in Supercapacitor with Redox-active Ionic Liquid Electrolyte Wang, Yanyu 10 1900 (has links) No description available. Redox-active ionic liquid Supercapacitors Faradaic reaction Solid-state NMR Electrochemical dilatometry Liquide ionique électroactif Supercapacité électrochimique Réaction faradique Dilatométrie électrochimique
146	Development and characterization of metal oxide semiconductor films deposited by solution precursor thermal spray process / Confection et caractérisation de revêtements d'oxydes métalliques semi-conducteurs par projection thermique, à partir de solutions des éléments précurseurs (techniques "SPTS"). Yu, Zexin 12 December 2018 (has links) Les procédés de photodégradation, de conversion photocatalytique du CO2 et la technologie des supercondensateurs représentent des options intéressantes pour palier aux problèmes environnementaux et pour apporter des réponses à la crise énergétique. Dans ces trois domaines, les matériaux à base d'oxydes métalliques sont très prometteurs. Cependant, les voies classiques (c'est-à-dire par voies hydrothermales ou de sol-gels) présentent un certain nombre d’inconvénients tels que leur longues durées de préparation et leurs rendements limités. En outre, la mise en oeuvre de nanopoudres suppose une opération de post-filtration dans les procédés de photodégradation et l’utilisation supplémentaire d’un liant dans la confection d’électrodes de supercondensateurs, ce qui non seulement réduit les performances respectives de ces deux procédés mais entrave également leur développement au niveau industriel. Dans cette thèse, les technologies SPPS (Solution Precursor Plasma Spray) et SPFS (Solution Precursor Flame Spray) ont été introduites pour préparer des films d'oxydes métalliques à base de ZnO, en bénéficiant des avantages de rapidité et simplicité de ces techniques de formation de dépôts. Les films ainsi obtenues ont ensuite été testés dans des expériences de photodégradation, de conversion photocatalytique du CO2 et sous forme de supercondensateurs. Tout d'abord, à notre connaissance, c'est la première fois que l'on synthétise directement des nanostructures de ZnO (par exemple des nanotubes ou des nanofils) par des procédés SPPS. Ces films nanostructurés et hiérarchisés présentent non seulement une croissance préférentielle le long du plan cristallin (002), mais contiennent aussi des lacunes d'oxygène dans leurs réseaux. La mise en œuvre de simulations DFT a permis de proposer un mécanisme possible de croissance des nanostructures de ZnO lors de leur synthèse par la voie SPPS. Deuxièmement, divers films “composites”, constitués de ZnO et d’un second oxide “MO” ont également été préparés par SPPS afin de réduire les bandes d'énergie interdites. Dans cette partie de la thèse, nous avons étudié l’effet du rapport molaire MO/ZnO sur la structure des films MO/ZnO obtenus (M = Mn et Cu); nous avons aussi préparé, par cette nouvelle méthode, des films fins CuO/ZnO et CeO2/ZnO ainsi que des films de ZnO “décorés”. Troisièmement, des films mettant en œuvre des structures du type spinelle (tels que les oxydes mixtes ZnFe2O4, NiCo2O4, ZnCo2O4 et Co3O4) ont également été synthétisés et déposés à l’aide des techniques SPPS et SPFS, ceci en raison de leur grand intérêt pour les applications susmentionnées. Il a été constaté que les structures obtenues sont très sensibles aux rapports MO/ZnO et que les morphologies de surface dépendent davantage des paramètres d'injection des solutions. En outre, la puissance de la torche joue un rôle plus critique dans la synthèse in situ de la phase spinelle binaire que la température de préchauffage du substrat. Enfin, la voie de préparation par SPPS favorise la formation de dépôts de textures floconneuses, notamment dans le cas des films de NiCo2O4 et Co3O4, tandis que des particules de formes sphériques ont été plutôt observées dans les échantillons préparés par la voie SPFS... / The fields of research dealing with photodegradation, photocatalytic conversion of CO2 and supercapacitors are important to address environmental problems and respond to the energy crisis. Metal oxides are promising materials in these three domains. However, the conventional routes (i.e. hydrothermal, sol-gel) suffer from major deficiencies, namely their multi-step natures, their long preparation duration and small-scaled yields. Moreover, the usage of nanopowders implies a post-filtration operation at the end of the photodegradation processes and requires an additional binder in supercapacitor electrodes. In this thesis, “Solution Precursor Plasma Spray” (SPPS) and “Solution Precursor Flame Spray” (SPFS) technologies have been introduced to develop metal oxide films in view of the three aforementioned applications, benefiting from the facility and rapidity advantages of this one-step process.Firstly, to our best knowledge, it is the first time that films composed by ZnO nanostructures (e.g. nanorods, nanowires) are directly synthesized via a SPPS process. These hierarchical ZnO nanostructured films not only exhibit preferential orientation growth along the (002) crystal plane, but also feature in-situ oxygen vacancies. As a result, a possible growth mechanism of ZnO nanostructures via SPPS route was proposed.Secondly, various metal oxides composite films containing ZnO and a second metal oxide were also prepared by SPPS in an effort to narrow the energy bandgaps. In this work, not only the effect of the molar CuO/ZnO and MnO/ZnO ratio was investigated, but also laminated CuO/ZnO and CeO2/ZnO films and CuO, Co3O4 and Fe2O3 decorated ZnO nanorods films were pioneeringly deposited via this novel route.Thirdly, films involving spinel-type materials (including ZnFe2O4, NiCo2O4, ZnCo2O4 and Co3O4) were also synthesized and deposited by the SPPS and SPFS technologies, owing to their high-interest in the aforementioned applications. We found that the phase compositions are more sensitive to the Fe/Zn and Ni/Co ratios and that the surface morphologies are more dependent on the patterns of the solution injection. In addition, the power of the torch plays a more critical role on the in-situ synthesis of binary spinel phase. Besides, the SPPS route promotes the formation of flake-like particles both in the NiCo2O4 and Co3O4 films, while sphere-like particles were observed in the SPFS-prepared samples.Finally, some as-prepared films were selected to evaluate their performances within the three applications. On the one hand, Orange II was successfully (100%) degraded within 2h under UV irradiation and about 85% was removed within 6h under visible light irradiation. On the other hand, Co3O4 samples exhibited specific capacitances up to 1190 F g−1 with a retention capacity of 136% after 2500 cycles at a 20 mV/s scanning rate in 2 M KOH electrolyte. Finally, when using ZnCo2O4 as photocatalyst, CO2 was converted into CO by visible light irradiation with a maximum turnover number as high as 61.38 and a selectivity as high as 90.5 %.Overall, this work not only improves the performances of the three studied processes thanks to the use of novel, fast preparation methods, but also suggests that “Solution Precursor Thermal Spray” should be a highly promising technology for further, alternative functional applications that involve finely structured metal oxides film. Précurseur de solution thermal spray Films d'oxyde métallique Nanostructures Dégradation photocatalytique Supercondensateurs Conversion photocatalytique du CO2 Solution precursor thermal spray Metal oxide films Nanostructures Photocatalytic degradation Supercapacitors Photocatalytic Conversion of CO2 543 620.1
147	Studies On Nanostructured Transition Metal Oxides For Lithium-ion Batteries And Supercapacitoris Ragupathy, P 08 1900 (has links) Rechargeable Li-ion batteries and supercapacitors are the most promising electrochemical energy storage devices in terms of energy density and power density, respectively. Recently, nanostructured materials have gained enormous interest in the field of energy technology as they have special properties compared to the bulk. Commercially available Li-ion batteries, which are the most advanced among the rechargeable batteries, utilize microcrystalline transition metal oxides as cathode materials which act as lithium insertion hosts. To explore better electrochemical performance the use of nanomaterials instead of conventional materials would be an excellent alternative. High Li-ion insertion at high discharge rates causes slow Li+ transport which in turn results in concentration polarization of lithium ions within the electrode material, causing a drop in cell voltage. This eventually, leads in termination of the discharge process before realizing the maximum capacity of the electrode material being used. This problem can be addressed by decreasing the average particle size which leads to an increase in surface area of the electrode material. Nanostructured materials, because of their high surface area and large surface to volume ratio, to some extent can overcome the problem of slow diffusion of ions. Supercapacitors are electrical energy storage devices which can deliver large energy in a short time. A supercapacitor can be used as an auxiliary energy device along with a primary source such as a battery or a fuel cell to achieve power enhancement in short pulse applications. Active materials for supercapacitors are classified into three categories: (i) carbonaceous materials, (ii) conducting polymers and (iii) metal oxides. Among the materials studied over the years, metal oxides have been considered as attractive electrode materials for supercapacitors due to the following merits: variable oxidation state, good chemical and electrochemical stability, ease of preparation and handling. The performance of supercapacitors can be enhanced by moving from bulk to nanostructured materials. The theme of the thesis is to explore novel routes to synthesize nanostructured materials for Li-ion batteries and supercapacitors, and to investigate their physical and electrochemical characteristics. Chapter I is an introduction of various types of electrochemical energy systems such as battery, fuel cell and supercapacitor. A brief review is made on electrode materials for Li-ion batteries and supercapacitors, and nanostructured materials. Chapter II deals with the study of nanostrip orthorhombic V2O5 synthesized by a two-step procedure, with the formation of a vanadyl ethylene glycolate precursor and post-calcination treatment. The precursor and the final product are characterized for phase and composition by powder X-ray diffraction (XRD), infrared (IR) spectroscopy, thermal analysis (TGA) and X-ray photoelectron spectroscopy (XPS). The morphological changes are investigated using field emission scanning electron microscopy (FE-SEM) and high resolution transmission electron microscopy (HRTEM). It is found that the individual strips have the following dimensions, length: 1.3 μm, width: 332 nm and thickness: 45 nm. The electrochemical lithium intercalation and de-intercalation of nanostrip V2O5 is investigated by cyclic voltammetry (CV), galvanostatic charge-discharge cycling, galvanostatic intermittent titration technique (GITT) and electrochemical impedance spectroscopy. Chapter III describes the synthesis of nanoparticels of LiMn2O4 by microwave assisted hydrothermal method. The phase and purity of spinel LiMn2O4 are confirmed by powder XRD analysis. The morphological studies are carried out using FE-SEM and HRTEM. The electrochemical performance of spinel LiMn2O4 is studied by using CV and galvanostatic charge-discharge cycling. The initial discharge capacity is found to be about 89 mAh g-1 at a current density of 21 mA g-1 with reasonably good cyclability. Chapter IV deals with synthesis of MoO2 nanoparticles through ethylene glycol medium and its electrochemical characterization. XRD data confirms the formation MoO2 on monoclinic phase, space group P21/c. Polygon shape of MoO2 is observed in HRTEM. MoO2 facilitates reversible insertion-extraction of Li+ ions between 0.25 to 3.0 V vs. Li/Li+. CV and galvanostatic charge-discharge cycling are conducted on this anode material to complement the electrochemical data. Chapter V reports the synthesis of nanostructured MnO2 at ambient conditions by reduction of potassium permanganate with aniline. Physical characterization is carried out to identify the phase and morphology. The as prepared MnO2 is amorphous and it contains particles of 5 to 10 nm in diameter. On annealing at a temperature > 400 °C, the amorphous MnO2 attains crystalline α-phase with a concomitant change in morphology. A gradual conversion of nanoparticles to nanorods (length 500-750 nm and diameter 50-100 nm) is evident from SEM and TEM studies. High resolution TEM images suggest that nanoparticles and nanorods grow in different crystallographic planes. The electrochemical lithium intercalation and de-intercalation of nanorods was performed by (CV) and galvanostatic charge-discharge cycling. The initial discharge capacity of nanorod α-MnO2 is found to be about 197 mAh g-1 at a current density of 13.0 mA g-1. Capacitance behavior of amorphous MnO2 is studied by CV and galvanostatic charge-discharge cycling in a potential range from -0.2 to 1.0 V vs. SCE in 0.1 M sodium sulphate solution. The effect of annealing on specific capacitance is also investigated. Specific capacitance of about 250 F g-1 is obtained for as prepared MnO2 at a current density of 0.5 mA cm-2 (0.8 A g-1). Chapter VI pertains to electrochemical supercapacitor studies on nanostructured MnO2 synthesized by polyol method. Although X-ray diffraction (XRD) pattern of the as synthesized nano-MnO2 shows poor crystallinity, it is found that it is locally arranged in δ-MnO2 type layered structure composed of edge-shared network of MnO6 octahedra by Mn K-edge X-ray Absorption Near Edge Structure (XANES) measurement. Annealed MnO2 shows high crystalline tunneled based α-MnO2 as confirmed by powder XRD pattern and XANES. As synthesized MnO2 exhibits good cyclability as an electrode material for supercapacitor. In Chapter VII, capacitance behavior of nanostrip V2O5, TiO2 coated V2O5 and nanocomposites of PEDOT/V2O5 are presented. Structural and morphological studies are carried out by powder XRD, IR, TGA, SEM and TEM. Cyclic voltammogram of pristine V2O5 shows the regular rectangular shape indicating the ideal capacitance behavior in aqueous 0.1 M K2SO4. The SC value of pristine V2O5 is found to be about 100 F g-1. Nanostrip V2O5 is modified with TiO2 using titanium isobutoxide to enhance the capacitance retention upon cycling. Only 48 % of the initial capacitance remains in the case of pristine V2O5 after 100 cycles, while TiO2 coated V2O5 exhibits better cyclability with capacitance of 70 % of the initial capacitance. The capacitance retention is attributed to the presence of TiO2 on the surface of V2O5 which prevents the vanadium dissolution into the electrolyte. Microwave assisted hydrothermally synthesized PEDOT/V2O5 nanocomposites are utilized as capacitor materials. The initial SC of PEDOT/V2O5 (237 F g-1) is higher than that of either pristine V2O5 or PEDOT. The enhanced electrochemical performance is attributed to synergic effect and an enhanced bi-dimensionality. Details of the above studies are described in the thesis with a conclusion at the end of each Chapter. Supercapacitors Lithium-ion Batteries Nanostructured Materials Transition Metal Oxides Capacitors Electrochemical Energy Storage Systems Electrode Materials Fuel Cells Li-ion Batteries V2O5 LiMn2O4 Molybdenum Dioxide TiO2 Manganese Oxide MnO2 PEDOT/V2O5 MoO2 Electrochemistry
148	Carbon Nanotubes: Chemical Vapor Deposition Synthesis and Application in Electrochemical Double Layer Supercapacitors Turano, Stephan Parker 08 March 2005 (has links) Carbon nanotubes (CNTs) have become a popular area of materials science research due to their outstanding material properties coupled with their small size. CNTs are expected to be included in a wide variety of applications and devices in the near future. Among these devices which are nearing mass production are electrochemical double layer (ECDL) supercapacitors. The current methods to produce CNTs are numerous, with each synthesis variable resulting in changes in the physical properties of the CNT. A wide array of studies have focused on the effects of specific synthesis conditions. This research expands on earlier work done using bulk nickel catalyst, alumina supported iron catalyst, and standard chemical vapor deposition (CVD) synthesis methods. This work also investigates the effect of an applied voltage to the CVD chamber during synthesis on the physical nature of the CNTs produced. In addition, the work analyzes a novel nickel catalyst system, and the CNTs produced using this catalyst. The results of the effects of synthesis conditions on resultant CNTs are included. Additionally, CNT based ECDL supercapacitors were manufactured and tested. Scanning electron microscope (SEM) analysis reveals that catalyst choice, catalyst thickness, synthesis temperature, and applied voltage have different results on CNT dimensions. Nanotube diameter distribution and average diameter data demonstrate the effect of each synthesis condition. Additionally, the concept of an alignment parameter is introduced in order to quantify the effect of an electric field on CNT alignment. CNT based ECDL supercapacitors testing reveals that CNTs work well as an active material when a higher purity is achieved. The molarity of the electrolyte also has an effect on the performance of CNT based ECDL supercapacitors. On the basis of this research, we conclude that CNT physical dimensions can be moderately controlled based on the choice of synthesis conditions. Also, the novel nickel catalyst system investigated in this research has potential to produce bulk quantities of CNT under specific conditions. Finally, purified CNTs are recommended as a suitable active material for ECDL supercapacitors. Nanomaterials Nanotechnology ECDL Supercapacitor CVD Chemical vapor deposition CNTs Carbon nanotubes Nickel catalysts Carbon Chemical vapor deposition Synthesis Electric double layer Nanotubes Synthesis
149	Development of Metal Nanoparticle-Doped Polyanilino-Graphene Oxide High Performance Supercapacitor Cells Dywili, Nomxolisi Ruth January 2018 (has links) Philosophiae Doctor - PhD (Chemistry) / Supercapacitors, also known as ultracapacitors or electrochemical capacitors, are considered one of the most important subjects concerning electricity or energy storage which has proven to be problematic for South Africa. In this work, graphene oxide (GO) was supported with platinum, silver and copper nanoparticles anchored with dodecylbenzenesulphonic acid (DBSA) doped polyaniline (PANI) to form nanocomposites. Their properties were investigated with different characterization techniques. The high resolution transmission electron microscopy (HRTEM) revealed GO's nanosheets to be light, flat, transparent and appeared to be larger than 1.5 ?m in thickness. This was also confirmed by high resolution scanning electron microscopy (HRSEM) with smooth surfaces and wrinkled edges observed with the energy dispersive X-ray analysis (EDX) confirming the presence of the functional groups such as carbon and oxygen. The HRTEM analysis of decorated GO with platinum, silver and copper nanoparticles (NPs) revealed small and uniformly dispersed NPs on the surface of GO with mean particle sizes of 2.3 ± 0.2 nm, 2.6 ± 0.3 nm and 3.5 ± 0.5 nm respectively and the surface of GO showed increasing roughness as observed in HRSEM micrographs. The X-ray fluorescence microscopy (XRF) and EDX confirmed the presence of the nanoparticles on the surface of GO as platinum, silver and copper which appeared in abundance in each spectra. Anchoring the GO with DBSA doped PANI revealed that single GO sheets were embedded into the polymer latex, which caused the DBSA-PANI particles to become adsorbed on their surfaces. This process then appeared as dark regions in the HRTEM images. Morphological studies by HRSEM also supported that single GO sheets were embedded into the polymer latex as composite formation appeared aggregated and as bounded particles with smooth and toothed edges. Energy crisis Supercapacitors Graphene oxide Reduced graphene oxide Platinum nanoparticles Silver nanoparticles Copper nanoparticles DBSA doped PANI Electrolytes Galvanostatic charge-discharge Specific discharge capacitance Specific charge capacitance Specific power Specific energy
150	Conversor modular multinível aplicado a sistema híbrido de armazenamento de energia Pinto, Jonathan Hunder Dutra Gherard 19 February 2018 (has links) Submitted by Geandra Rodrigues (geandrar@gmail.com) on 2018-03-27T13:46:07Z No. of bitstreams: 1 jonathanhunderdutragherardpinto.pdf: 6016290 bytes, checksum: 50eab93d008d20c4a60c851574b2c6f3 (MD5) / Approved for entry into archive by Adriana Oliveira (adriana.oliveira@ufjf.edu.br) on 2018-03-27T13:57:34Z (GMT) No. of bitstreams: 1 jonathanhunderdutragherardpinto.pdf: 6016290 bytes, checksum: 50eab93d008d20c4a60c851574b2c6f3 (MD5) / Made available in DSpace on 2018-03-27T13:57:34Z (GMT). No. of bitstreams: 1 jonathanhunderdutragherardpinto.pdf: 6016290 bytes, checksum: 50eab93d008d20c4a60c851574b2c6f3 (MD5) Previous issue date: 2018-02-19 / Este trabalho tem como contribuição o desenvolvimento de uma estratégia de equa-lização das tensões em um conversor multinível modular, como parte integrante de um sistema híbrido de armazenamento de energia. O conversor modular multinível realiza a conexão em série de módulos supercapacitores, o que possibilita aumentar a ten-são sem prejudicar a transferência rápida de energia. Em relação à outras topologias, este trabalho permite reduzir a quantidade, volume e massa do elemento magnético da estrutura do conversor. Um banco de baterias de íons de lítio também integra o sistema por intermédio de um conversor estático. Como é a fonte de maior densidade de energia, fornece a potência média requerida pelo carga. A associação com uma fonte de transferência rápida de energia permite aumentar o desempenho dinâmico, a eficiência energética e a vida útil da bateria. Com efeito, tem-se um sistema híbrido de armazenamento de energia que requer estratégias de gestão para múltiplas fontes de suprimento. Os resultados simulados considerando a estimativa da demanda de po-tência de um protótipo de veículo elétrico, são adequados e propiciam os fundamentos necessários para a construção de um protótipo. / This work is a contribution to develop a strategy equalization of tensions in a mo-dular multilevel converter as part of a hybrid system energy storage. The multilevel modular converter realizes the series connection of supercapacitor modules, which al-lows to increase the voltage without cause damages to the quick energy transfer. In relation to other topologies, it allows reduction of the quantity, volume and mass of the magnetic element of the converter structure. A lithium-ion battery bank also integrates the system via a voltage boost converter. This battery is the source of high energy density, which provides the average power required by the load. The association with a fast transfer power source allows for increased dynamic performance, energy efficiency and service life. In fact, there is a hybrid energy storage system that requires mana-gement strategies for multiple sources of supply. The simulated results were obtained considering the power demand estimation of an electric vehicle prototype. CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA Baterias eletroquímicas Conversor modular multinível Frenagem re-generativa Gestão de múltiplas fontes Supercapacitores Veículos elétricos Electrochemical batteries Modular multilevel converter Regenerative bra-king Management of multiple sources Hybrid system energy storage Supercapacitors Electric vehicles

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