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Interfaces moleculares baseadas em nanocompósitos de VXG com espécies polimetaladas / Molecular-based interfaces nanocomposites VXG with polymetalated speciesAnaíssi, Fauze Jacó 10 March 2000 (has links)
Nesta tese investigamos o comportamento eletroquímico da matriz lamelar de xerogel de pentóxido de vanádio(V) hidratado (VXG), visando desenvolver interfaces moleculares e eletrodos modificados. A partir da suspensão do gel de V2O5.nH2O, geramos os filmes lamelares de VXG sobre a superfície do eletrodo de trabalho. Inicialmente, os filmes de VXG consistem de regiões heterogêneas, que podem ser diferenciadas espectroeletroquimicamente. Após tratamento eletroquímico, esses filmes atingem uma condição eletroquímica estacionária, sofrendo um colapso e formando uma estrutura tipo banda uniforme. Esses filmes de VXG condicionados, foram utilizados como interfaces de espécies moleculares eletroativas. Em paralelo, interagimos o VXG com a argila bentonita, e obtivemos um xerogel floculento verde em solução aquosa, denotado BV, cuja evidência mais forte dessa interação foi obtido pelo espectro de FTIR, em função do surgimento de um forte pico em 835 cm-1, atribuído ao estiramento V-O-Si. A interação com a zeólita13X, resultou num sólido amarelo devido à troca de íons Na+ pelo grupo VO3+, denotado ZV. A troca iônica foi evidenciada pela análise de ICP-AES, que determinou uma quantidade grande de íons Na+ na solução sobrenadante, aproximadamente 225 mg/L contra 28 e 25,4 mg/L das soluções originais de VXG e zeólita13X, respectivamente. Eletroquimicamente, os compósito BV e ZV, despontam como materiais modificadores de eletrodos muito atraentes, combinando a boa condutividade dos filmes de VXG com as propriedades de troca iônica e de intercalação das argilas e das zeólitas. / The electrochemical behavior of hydrated vanadium(V)-oxide xerogels (denoted VXG), has been investigated, aiming the development of molecular interfaces and modified electrodes. Layered vanadium(V)- oxide xerogel films have been generated, in a controlled way, by the direct deposition de precise amounts of the polyvanadic acid solution onto the electrode surface. Initially, the layered VGX films consist of heterogeneous regions, which can be differentiated spectroelectrochemically. However, after the electrochemical treatment, those films reach a stationary electrochemical condition, collapsing into a uniform band type structure. The conditioned layered VXG films have been utilized as interfaces of electroactive molecular species. In parallel, the VXG suspension has been combined with a montmorillonite clay, yielding a green flocculent xerogel in suspension, here denoted BV. Strong evidence of polyvanadate-bentonite interaction has been provided by the FTIR spectra, from the appearance of a strong peak in 835 cm-1, ascribed to the a new V-O.-Si stretching vibration. The VXG suspension has also been combined with zeolite 13X, resulting a yellow solid, envolving ionic exchange of Na+ ions by VO3+; this solid has been denoted ZV. Ionic exchange has been evidenced by ICP-AES analyses. A promissing use of the new materiaIs as molecular interfaces has been demonstated, exploiting the good conductivity and intercalation properties of VXG and BV, as well as, the ion exchange properties of ZV.
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Xerogel de pentóxido de vanádio: novas abordagens na caracterização e aplicações / Vanadium pentoxide: new insights in their characterization and applicationsHuila, Manuel Fernando Gonzalez 19 April 2013 (has links)
Um estudo refinado dos filmes derivados do gel de pentóxido de vanádio foi realizado por meio de técnicas espectroscópicas e microscópicas visando compreender melhor as características deste material na escala microscópica. Foi demonstrado que o gel de pentóxido de vanádio é uma suspensão de nanopartículas anisotrópicas que se mantêm estáveis mesmo em altas concentrações. As propriedades estruturais e espectroscópicas destas nanopartículas foram revistas e discutidas no estado da arte. Em paralelo foi possível investigar fenômenos como a transição de fase induzida por laser e desenvolver aplicações tecnológicas em áreas como litografia e sensoriamento de gases. Ficou destacada nesta tese o grande potencial de investigação da microscopia Raman confocal na área de nanomateriais. / A refined study of films derived from vanadium pentoxide gel was carried out based on spectroscopic and microscopic techniques, aiming a better understanding of this material on a microscopic scale. It was demonstrated that the vanadium pentoxide gel consists of a suspension of anisotropic nanoparticles which remains stable even at high concentrations. The structural and spectroscopic properties of such nanoparticles were reviewed and discussed, providing new insights at the state of the art. It was also investigated the occurrence of some relevant phenomena, such as the laser induced phase transition, and to develop new technological applications in areas such as gas sensing and lithography. The collection of results described in thesis highlighted a great research potential of confocal Raman microscopy, in the field of nanomaterials.
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Interfaces moleculares baseadas em nanocompósitos de VXG com espécies polimetaladas / Molecular-based interfaces nanocomposites VXG with polymetalated speciesFauze Jacó Anaíssi 10 March 2000 (has links)
Nesta tese investigamos o comportamento eletroquímico da matriz lamelar de xerogel de pentóxido de vanádio(V) hidratado (VXG), visando desenvolver interfaces moleculares e eletrodos modificados. A partir da suspensão do gel de V2O5.nH2O, geramos os filmes lamelares de VXG sobre a superfície do eletrodo de trabalho. Inicialmente, os filmes de VXG consistem de regiões heterogêneas, que podem ser diferenciadas espectroeletroquimicamente. Após tratamento eletroquímico, esses filmes atingem uma condição eletroquímica estacionária, sofrendo um colapso e formando uma estrutura tipo banda uniforme. Esses filmes de VXG condicionados, foram utilizados como interfaces de espécies moleculares eletroativas. Em paralelo, interagimos o VXG com a argila bentonita, e obtivemos um xerogel floculento verde em solução aquosa, denotado BV, cuja evidência mais forte dessa interação foi obtido pelo espectro de FTIR, em função do surgimento de um forte pico em 835 cm-1, atribuído ao estiramento V-O-Si. A interação com a zeólita13X, resultou num sólido amarelo devido à troca de íons Na+ pelo grupo VO3+, denotado ZV. A troca iônica foi evidenciada pela análise de ICP-AES, que determinou uma quantidade grande de íons Na+ na solução sobrenadante, aproximadamente 225 mg/L contra 28 e 25,4 mg/L das soluções originais de VXG e zeólita13X, respectivamente. Eletroquimicamente, os compósito BV e ZV, despontam como materiais modificadores de eletrodos muito atraentes, combinando a boa condutividade dos filmes de VXG com as propriedades de troca iônica e de intercalação das argilas e das zeólitas. / The electrochemical behavior of hydrated vanadium(V)-oxide xerogels (denoted VXG), has been investigated, aiming the development of molecular interfaces and modified electrodes. Layered vanadium(V)- oxide xerogel films have been generated, in a controlled way, by the direct deposition de precise amounts of the polyvanadic acid solution onto the electrode surface. Initially, the layered VGX films consist of heterogeneous regions, which can be differentiated spectroelectrochemically. However, after the electrochemical treatment, those films reach a stationary electrochemical condition, collapsing into a uniform band type structure. The conditioned layered VXG films have been utilized as interfaces of electroactive molecular species. In parallel, the VXG suspension has been combined with a montmorillonite clay, yielding a green flocculent xerogel in suspension, here denoted BV. Strong evidence of polyvanadate-bentonite interaction has been provided by the FTIR spectra, from the appearance of a strong peak in 835 cm-1, ascribed to the a new V-O.-Si stretching vibration. The VXG suspension has also been combined with zeolite 13X, resulting a yellow solid, envolving ionic exchange of Na+ ions by VO3+; this solid has been denoted ZV. Ionic exchange has been evidenced by ICP-AES analyses. A promissing use of the new materiaIs as molecular interfaces has been demonstated, exploiting the good conductivity and intercalation properties of VXG and BV, as well as, the ion exchange properties of ZV.
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Nanocompósitos híbridos metal-orgânicos baseados em pentóxido de vanádio / Hybrid metal-organic nanocomposites based on vandium pentoxideRonaldo Adriano Timm 12 May 2008 (has links)
Esta tese focaliza o desenvolvimento de sistemas nanoestruturados através da intercalação de espécies moleculares e supramoleculares em matrizes lamelares de xerogel de pentóxido de vanádio, visando sua utilização como interfaces em dispositivos sensoriais. Nela se explora principalmente as características dos sistemas supramoleculares, dando destaque ao fato de estarem intimamente relacionadas com a natureza das espécies neles presentes, bem como com o tipo de interação, organização e disposição das mesmas. Nesse contexto, são descritos trabalhos desenvolvidos com V2O5.H2O, o material base do projeto, em combinação com outros materiais, para gerar compósitos com potenciais aplicações na área de sensores. Nessa linha são apresentados principalmente os resultados obtidos para a intercalação de metaloporfirinas no pentóxido de vanádio. Também foi dedicada especial atenção à 4,5-diamino-2,6-dimercaptopirimidina (DADMcP), como espécie intercalante em matriz de pentóxido de vanádio, motivado pelas suas propriedades eletroquímicas interessantes para aplicações em baterias de alta densidade de carga. / Nanostructured systems based on the intercalation of molecular and supramolecular species into lamellar vanadium pentoxide xerogels are focused on this Thesis. The exciting characteristics of the supramolecular systems which are closely related to the nature, interaction and organization of the chemical species involved, have been exploited aiming their application in sensor devices. Special emphasis has been given to the research dealing with vanadium(V) oxide in combination with many other suitable species for generating composite materials exhibiting potential application for sensing purposes. Along this line, the results obtained from the intercalation of metalloporphyrins into the lamellar vanadium(V) oxide matrix have been discussed in great detail. Another system, consisting of 4,5-diamine-2,6-dimercaptopyrimidine (DADMcP) as the intercalating species in vanadium(V) oxide, has also been investigated, stimulated by its promising use in high charge density batteries.
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Xerogel de pentóxido de vanádio: novas abordagens na caracterização e aplicações / Vanadium pentoxide: new insights in their characterization and applicationsManuel Fernando Gonzalez Huila 19 April 2013 (has links)
Um estudo refinado dos filmes derivados do gel de pentóxido de vanádio foi realizado por meio de técnicas espectroscópicas e microscópicas visando compreender melhor as características deste material na escala microscópica. Foi demonstrado que o gel de pentóxido de vanádio é uma suspensão de nanopartículas anisotrópicas que se mantêm estáveis mesmo em altas concentrações. As propriedades estruturais e espectroscópicas destas nanopartículas foram revistas e discutidas no estado da arte. Em paralelo foi possível investigar fenômenos como a transição de fase induzida por laser e desenvolver aplicações tecnológicas em áreas como litografia e sensoriamento de gases. Ficou destacada nesta tese o grande potencial de investigação da microscopia Raman confocal na área de nanomateriais. / A refined study of films derived from vanadium pentoxide gel was carried out based on spectroscopic and microscopic techniques, aiming a better understanding of this material on a microscopic scale. It was demonstrated that the vanadium pentoxide gel consists of a suspension of anisotropic nanoparticles which remains stable even at high concentrations. The structural and spectroscopic properties of such nanoparticles were reviewed and discussed, providing new insights at the state of the art. It was also investigated the occurrence of some relevant phenomena, such as the laser induced phase transition, and to develop new technological applications in areas such as gas sensing and lithography. The collection of results described in thesis highlighted a great research potential of confocal Raman microscopy, in the field of nanomaterials.
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DESIGN AND FABRICATION OF HIGH CAPACITY LITHIUM-ION BATTERIES USING ELECTRO-SPUN GRAPHENE MODIFIED VANADIUM PENTOXIDE CATHODESAmirhossein Ahmadian (7035998) 17 December 2020 (has links)
<p>Electrospinning
has gained immense interests in recent years due to its potential application
in various fields, including energy storage application. The V<sub>2</sub>O<sub>5</sub>/GO
as a layered crystal structure has been demonstrated to fabricate nanofibers
with diameters within a range of ~300nm through electrospinning technique. The porous,
hollow, and interconnected nanostructures were produced by electrospinning formed
by polymers such as Polyvinylpyrrolidone (PVP) and Polyvinyl alcohol (PVA),
separately, as solvent polymers with electrospinning technique. </p>
<p> </p>
<p>In this study, we investigated the synthesis of a graphene-modified nanostructured V<sub>2</sub>O<sub>5</sub> through modified sol-gel method and electrospinning
of V<sub>2</sub>O<sub>5</sub>/GO hybrid. Electrochemical
characterization was performed by utilizing Arbin Battery cycler,
Field Emission Scanning Electron
Microscopy (FESEM), X-ray powder diffraction (XRD), Thermogravimetric analysis (TGA), Mercury Porosimetery, and BET surface area
measurement. </p>
<p> </p>
<p>As compared to the
other conventional fabrication methods, our optimized sol-gel method, followed
by the electrospinning of the cathode material achieved a high initial capacity
of <b>342 mAh/g</b> at a high current density of 0.5C (171 mA/g) and the
capacity retention of ~80% after 20 cycles. Also, the prepared sol-gel method
outperforms the pure V<sub>2</sub>O<sub>5 </sub>cathode material, by obtaining
the capacity almost two times higher.</p>
<p>The results of
this study showed that post-synthesis treatment of cathode material plays a prominent
role in electrochemical performance of the nanostructured vanadium oxides. By controlling the
annealing and drying steps, and time, a small amount of pyrolysis carbon can be
retained, which improves the conductivity of the V<sub>2</sub>O<sub>5</sub>
nanorods. Also, controlled post-synthesis helped us to prevent aggregation of
electro-spun twisted nanostructured fibers which deteriorates the lithium
diffusion process during charge/discharge of batteries.</p>
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Fabrication of Inorganic Oxide Nanofibers Using Gas Jet Fiber Spinning Process and Their Applications in Photocatalytic OxidationGHOSH, MONOJ 16 October 2017 (has links)
No description available.
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A new chemical synthesis for vanadium sulfide as high performance cathodeWen Chao, Lee January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Since 1990s, rechargeable Li-ion batteries have been widely used in consumer electronics such as cell phones, global positioning systems (GPS), personnel digital assistants (PDA), digital cameras, and laptop computers. Recently Li-ion batteries received considerable attention as a major power source for electric vehicles. However, significant technical challenges still exist for widely deploying Li-ion batteries in electric vehicles. For instance, the energy density of Li-ion batteries is not high enough to support a long-distance commute. The Li-ion batteries used for the Nissan Leaf and Chevy Volt only can support 50 – 100 miles per charge. The cost of Li-ion battery packs in electric vehicles is still high. The battery pack for the Chevy Volt costs about $8,000, and the larger one in the Nissan Leaf costs about $12,000. To address these problems, new Li-ion battery electrode materials with high energy density and low cost should be developed. Among Li-ion battery cathode materials, vanadium pentoxide, V2O5, is one of the earliest oxides studied as a cathode for Li-ion batteries because of its low cost, abundance, easy synthesis, and high energy density. However, its practical reversible capacity has been limited due to its irreversible structural change when Li insertion is more than x = 1.
Tremendous efforts have been made over the last twenty years to improve the phase reversibility of LixV2O5 (e.g., 0 ≤ x ≤ 2) because of vanadium pentoxides’ potential use as high capacity cathodes in Li-ion batteries. In this thesis, a new strategy was studied to develop vanadium pentoxide cathode materials with improved phase reversibility. The first study is to synthesize vanadium oxide cathodes via a new chemical route – creating a
phase transformation from the vanadium sulfide to oxide. The β-Na0.33V2O5 was prepared via a new method of chemical synthesis, involving the chemical transformation of NaVS2 via heat-treatment at 600 °C in atmospheric air. The β-Na0.33V2O5 particles were well crystalized and rod-shaped, measuring 7–15 μm long and 1–3 μm wide with the formation of the crystal defects on the surface of the particles. In contrast to previous reports contained in the literature, Na ions were extracted, without any structural collapse, from the β -Na0.33V2O5 structure and replaced with Li ions during cycling of the cell in the voltage range, 1.5 V to 4.5 V. This eventually resulted in a fully reversible Li intercalation into the LixV2O5 structure when 0.0 ≤ x ≤ 2.0.
The second study is to apply the synthesis method to LiVS2 for the synthesis of β׳-LixV2O5 for use as a high performance cathode. The synthesis method is based on the heat treatment of the pure LiVS2 in atmospheric air. By employing this method of synthesis, well-crystalized, rod-shaped β׳-LixV2O5 particles 20 – 30 μm in length and 3 – 6 μm in width were obtained. Moreover, the surface of β׳-LixV2O5 particles was found to be coated by an amorphous vanadium oxysulfide film (~20 nm in thickness). In contrast to a low temperature vanadium pentoxide phase (LixV2O5), the electrochemical intercalation of lithium into the β׳-LixV2O5 was fully reversible where 0.0 < x < 2.0, and it delivered a capacity of 310 mAh/g at a current rate of 0.07 C between 1.5 V and 4 V. Good capacity retention of more than 88% was also observed after 50 cycles even at a higher current rate of 2 C.
The third study is the investigation of NaVS2 as a cathode intercalation material for sodium ion batteries. We have shown that reversible electrochemical deintercalation of x ~ 1.0 Na per formula unit of NaxVS2, corresponding to a capacity of ~200 mAh/g, is possible. And a stable capacity of ~120 mAh/g after 30 cycles was observed.
These studies show that the new chemical synthesis route for creating a phase transformation from the vanadium sulfide to oxide by heat treatment in air is a promising method for preparing vanadium oxide cathode material with high reversibility. Although this sample shows a relatively low voltage range compared with other cathodes such as LiCoO2 (3.8 V) and LiFePO4 (3.4 V), the large capacity of this sample is quite attractive in terms of increasing energy density in Li-ion batteries. Also, NaVS2 could be a promising cathode material for sodium ion batteries.
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