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Síntese de nanopartículas de óxido de vanádio obtidas pela decomposição de peróxido / Synthesis of Vanadium Oxide Nanoparticles obtained by the decomposition of peroxideAvansi Junior, Waldir 29 September 2010 (has links)
A utilização de novas rotas de síntese de materiais nanoestruturados tem levado à obtenção de materiais apresentando novas propriedades e aplicações. O presente trabalho teve como principal objetivo realizar a síntese e a caracterização de nanopartículas de óxido de vanádio obtidas pelo método da decomposição de peróxido utilizando o tratamento hidrotermal. Por meio do controle do tempo e da temperatura de síntese, foi possível obter nanoestruturas de pentóxido de vanádio com diferentes fases cristalinas e morfologias. Os resultados de espectroscopia Raman e difração de raios X (DRX) mostraram que o tratamento hidrotermal da solução em temperaturas de até 180oC, durante 2 horas, leva à formação da fase V2O5nH2O monoclínica, apresentando uma orientação preferencial na direção 00l. A partir desta temperatura, o material obtido passou a ter a fase ortorrômbica perdendo sua orientação preferencial. Através das medidas de termogravimetria (TG) foi observado que, dependendo da condição de síntese, as amostras apresentam diferentes quantidades de moléculas de água (H2O) intercaladas em sua estrutura. Imagens de microscopia eletrônica mostraram que as nanoestruturas obtidas podem possuir a forma de fitas, fios ou bastões. Utilizando a técnica de espectroscopia de absorção de raios X (XAS), foi possível verificar a presença de íons de V4+ nas amostras de fase monoclínica, o que não foi observado naquelas que possuem estrutura ortorrômbica. Pela técnica de XAS também foi possível constatar que as amostras de estrutura ortorrômbica possuem menor grau de desordem ao redor do átomo de vanádio. O estudo do mecanismo de crescimento da nanoestrutura de V2O5nH2O mostrou que ocorre um crescimento lateral, o qual pode ser descrito pelo mecanismo denominado Coalescência Orientada ou Oriented attachment (OA). Finalmente, através da decomposição do peróxido de vanádio, foi possível obter compostos vanadatos contendo cátions de Na+ em sua estrutura. / The use of new routes for nanostructured materials synthesis has lead to materials with new properties and applications. This PhD project aimed to realize the synthesis and the characterization of vanadium pentoxide nanoparticles obtained by peroxide decomposition using the hydrothermal treatment. By controlling synthesis time and temperature it was possible to achieve vanadium pentoxide nanoparticles with different crystalline phases and orphologies. The results of Raman spectroscopy and X-ray diffraction (XRD) showed that the hydrothermal treatment of the solution at temperatures up to 180oC for two hours leads to formation of the V2O5nH2O monoclinic phase with a preferential orientation on 00l direction. From this temperature on the material obtained began to present the orthorhombic phase misleading its preferential orientation. Through thermogravimetry (TG) measurements it was seen that depending on the synthesis condition the samples contains different amounts of water molecules (H2O) interleaved in their structure. Images of transmission electron microscopy (TEM) showed that the V2O5nH2O compound could have different morphologies such as ribbons, wires and rods. From X-Ray Absorption spectroscopy (XAS) measurements, it was observed the presence of V4+ ions in the monoclinic phase samples, which was not observed on orthorhombic structure samples. Through the XAS technique was also observed that the orthorhombic structure samples have a lower degree of disorder around the vanadium atom. Regarding the growth mechanism of these nanostructures, it was possible to verify that has been a wide growth which can be explained by the mechanism denominated Oriented Attachment (OA). Finally, through vanadium peroxide decomposition vanadates compounds containing Na+ cation in its structure were carried out.
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Síntese de nanofios de óxidos semicondutores para aplicações em dispositivos ópticos e eletrônicosSavu, Raluca [UNESP] 16 November 2009 (has links) (PDF)
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savu_r_dr_bauru.pdf: 10688901 bytes, checksum: 4c1846c73d88b2e598b43e7a14ea1b7c (MD5) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / A presente pesquisa teve como principal objetivo a obtenção de estruturas nanométricas de óxido de índio, óxido de estanho e óxido de zinco por evaporação térmica e síntese hidrotérmica e a construção e teste de sensores de gases e de fotodetectores de ultravioleta baseados nessas nanoestruturas. Foram realizados estudos da influência dos parâmetros experimentais das duas rotas de síntese usadas sobre as morfologias e as propriedades das estruturas. Para a obtenção das camadas nanoestruturadas por evaporação térmica foi especialmente construído um forno tubular que permitiu o controle da temperatura de deposição independente da temperatura de evaporação e da distância entre a fonte de evaporação e o substrato. Esses parâmetros, pouco explorados nas pesquisas reportadas na literatura, exerceram uma grande influência sobre a morfologia e as propriedades dos nanofios obtidos. O equipamento permitiu ainda um controle preciso da composição da atmosfera e da pressão de síntese. Na síntese química em solução, a construção de um reator hidrotérmico permitiu o estudo da influência da taxa de resfriamento sobre as dimensões, cristalinidade, morfologia e propriedades das nanoestruturas. Esse estudo, o primeiro do gênero na literatura, ressaltou a importância no controle deste parâmetro para sintetizar estruturas com propriedades melhoradas. As demais variáveis estudadas foram: a concentração das soluções, as camadas catalisadoras, a temperatura e o tempo de síntese. Foram testadas duas estratégias para a obtenção dos filmes nanoestruturados: spin-coating de suspensões de nanoestruturas sobre substratos de silício oxidado ou o crescimento das mesmas, durante a síntese, sobre substratos com camadas catalisadoras de zinco. Os nanofios e as camadas funcionais foram caracterizados por Difração de Raios-X (DRX), Microscopia Eletrônica de Varredura... / The subject of this thesis covers the synthesis and growth of indium, tin and zinc oxide nanostructures by thermal evaporation and hydrothermal synthesis and the fabrication and testing of gas sensors and ultraviolet photodetectors based on these nanosized structures. For both chemical and physical routes, the influence of processing conditions over the morphology, dimensions and electrical properties of the nanowires was investigated. In order to obtain nanostructured layers by thermal evaporation a tubular furnace was specifically builti, allowed the control of the source-substrate distance and the deposition temperature independently of the evaporation one. These parameters, slightly explored in the literature, granted a big influence over the nanowires morphology and properties. Moreover, the equipment permitted the control of deposition atmosphere and pressure. The design and assembly of a hydrothermal reactor allowed studying the influence of the cooling rate over the dimension, morphology, cristallinity and, consequently, the properties of the nanostructures. This study highlighted the importance of controlling this particular parameter in the hydrothermal process, yielding nanostructured materials with enhanced properties. Variables such as solution concentration, synthesis temperature and time, surfanctants and precursors were also explored in the hydrothermal process. In order to obtain nanostructured thin films using the chemical bath deposition, two processing techniques were employed: spin-coating of powder suspensions over oxidized silicon substrates and nanostructured anisotropic growth directly from solution using zinc coated substrates. The nanowires and the functional nanostructured layers were characterized by X-Ray Diffraction (XRD), Field Emission Scanning Electron Microscopy (FE - SEM), Transmission Electron Microscopy (TEM) and X-ray Photoelectron Spectroscopy (XPS)... (Complete abstract click electronic access below)
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Gas separation of steam and hydrogen mixtures using an α-alumina-Alumina supported NaA membrane / by S. MoodleyMoodley, Shawn January 2007 (has links)
Thesis (M. Ing. (Chemical Engineering))--North-West University, Potchefstroom Campus, 2008.
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Continuous and batch hydrothermal synthesis of metal oxide nanoparticles and metal oxide-activated carbon nanocompositesXu, Chunbao 15 August 2006 (has links)
Hydrothermal synthesis is a widely used technique for the preparation of fine particles. It can be carried out in batch or flow systems, although most studies have used batch reactors below 200 C. More recently, however, continuous hydrothermal synthesis has been employed in near- and supercritical water to obtain metal oxide particles. This technique offers tremendous promise for control of particle characteristics due to the rapidly changing properties of water with temperature and pressure in the critical region. However, the role of temperature in this process is not completely understood. Moreover, agglomeration of particles remains a problem in both batch and continuous hydrothermal techniques.
This work is concerned with the use of continuous hydrothermal synthesis at near-critical and supercritical conditions to obtain iron oxide and lithium iron phosphate nanoparticles. Factors that affect size, size-distribution, and morphology of nanoparticles were investigated and the results have been used to resolve differences in the literature concerning the effect of temperature on particle size. It was shown that agglomeration can be minimized by using a protective polymer coating and this appears to be an effective method to control particle size.
The continuous hydrothermal technique was also extended to materials other than metal oxides by synthesizing lithium iron phosphate. Differences in the particle sizes obtained using the batch and continuous methods were shown to be due to the different mechanisms of particle formation in the two techniques. Better particle characteristics (size, size distribution and morphology) were obtained using the continuous hydrothermal technique than using the batch hydrothermal method.
Iron oxide nanoparticles were also deposited on the surface and in the pores of activated carbon pellets in a batch reactor in order to minimize agglomeration of particles. The resulting iron oxide activated carbon nanocomposites exhibited significant catalytic performance in the oxidation of propanal. Therefore, the use of supercritical water to deposit metal oxide particles on hydrophobic surfaces offers promise for carbon-supported catalyst preparation without the use of toxic or noxious solvents.
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Hydrothermal-like Synthesis Of Hydroxyapatite From Calcium SulfatesBingol, Onur Rauf 01 October 2010 (has links) (PDF)
Synthesis of hydroxyapatite (Ca10(PO4)6(OH)2, HAp) from commercial grade plaster of paris (CaSO4&bull / 0.5H2O, PoP) and gypsum (CaSO4&bull / 2H2O) has been performed. HAp synthesis was achieved by reacting 1 M of (NH4)2HPO4 (or 0.5 M of (NH4)2HPO4) solutions with solid calcium sulfate precursors under ambient pressure (1 atm) and hydrothermal-like (2 ± / 0.2 atm, 120 ° / C) conditions. Under ambient conditions, HAp formation kinetics was investigated at 25 ° / C, 50 ° / C and 90 ° / C using 1 M of (NH4)2HPO4 solution. Conversion to HAp at such low temperature takes more than 21 days and it also promotes formation of additional calcium phosphate with HAp. At 25 ° / C, HAp formation started after 7 days accompanied with formation of brushite (CaHPO4&bull / 2H2O). At 50 ° / C no significant conversion was observed after 6 h. However, at 90 ° / C, phase pure HAp was formed after 2 h. On the other hand, under hydrothermal-like conditions, the HAp formation proceed much faster and it was also shown that HAp could be also synthesized from gypsum powders and bulk gypsum pellets. Using 1 M of (NH4)2HPO4 solution, HAp formation from PoP started 15 min and completed almost in 30 min, whereas 0.5 M of (NH4)2HPO4 reactant solution slowed down the conversion. The exact chemical identity of the HAp product of hydrothermal-like reaction was evaluated by post-synthesis calcinations and the thermal phase stability was related with the stoichiometry (Ca/P at ratio) of the HAp. The HAp phase was stable up to 600 ° / C and above 600 ° / C, &beta / -tricalcium phosphate (&beta / -Ca3(PO4)2, &beta / -TCP) was formed, suggesting that the resultant HAp was calcium-deficient. Mechanical testing by diametrical compression was performed to the HAp samples produced from bulk gypsum pellets. The strength was measured 1.2 MPa with highest solid to liquid (s:l) ratio 3.33 and decreased with s:l ratio. This change was found to be related with the porosity differences due to differences in s:l ratio. Additional mechanical tests were applied to the polycaprolactone (PCL) coated bulk HAp pellets for which the tensile strength was doubled. This study presents an easy and feasible method for production of HAp from a cheap and abundant calcium source &ndash / PoP. In addition, the findings provide a potential processing route for developing irregularly shaped bulk porous HAp structures.
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Gas separation of steam and hydrogen mixtures using an α-alumina-Alumina supported NaA membrane / by S. MoodleyMoodley, Shawn January 2007 (has links)
In this study, the feasibility of a NaA zeolite membrane for the gas phase separation of steam and hydrogen mixtures was determined. The Fischer-Tropsch (FT) process, which produces high value fuels and chemicals from coal and natural gas, can be greatly improved upon by the selective removal of water from the FT reactor product stream. According to the FT reaction kinetics, the rate of reaction increases with the partial pressure of hydrogen but is adversely affected the presence of water in the reactor product stream. Chemisorbed water on the surface of the metal catalysts also enhances deactivation due to sintering and fouling. The use of a zeolite membrane reactor is well equipped to serve the purpose of in-situ water removal as it can facilitate the separation of chemical components from one another in the presence of catalytic reactions. The LTA type zeolite membrane NaA or zeolite 4A, in particular, is well suited for the separation of polar (H2O) from non-polar (H2) molecules because of its high hydrophilicity. NaA has also been identified as an excellent candidate for selective water removal applications due its high adsorption affinity and capacity for water.
The NaA membrane used in this study was manufactured by means of the in-situ crystallisation method where the growth of crystals on the inside surface of a centrifugally casted a-alumina support was favoured. Scanning electron microscopy (SEM) analyses performed on the membrane after a double hydrothermal synthesis indicated that the surface topology was rough and that the zeolite crystals formed were not uniform in size. Overall, the membrane thickness varied between 6.5 and 8.0 flm. An evaluation of the membrane quality was made possible through permeation experiments involving SF6 and Hz. The calculated Hz/SF6 permselectivity in this study was found to be 9.78, which despite being higher than the Knudsen diffusion selectivity of 8.54, confirmed the presence of intercrystalline defects or non-zeolitic pores in the membrane. Experiments concerning pure component and binary mixture permeation of steam and hydrogen through the supported NaA membrane were conducted over a temperature range of 115°C to 160 °c for binary hydrogen/steam mixtures, 25°C to 160°C for pure hydrogen and 130°C to 170°C for pure steam. For the permeation of pure component hydrogen, a local maximum in its permeance having a value of 224 x 10'°8 mol.m,z.s'!.Pa'! was reached at a system pressure and temperature of 6.875 bar and 75°C respectively. For the permeation of pure component steam
through NaA, the effects of capillary condensation in the pores and defects of the zeolite membrane resulted in a decrease in steam permeance as a function of absolute pressure for temperatures lower than 160 °c. Once the effects of capillary condensation had receded, maxima in the steam permeances as a function of temperature corresponding to values of 70 x 10,08, 65 X 10,08 and 75 x 10,08 mol.m•2.s'I.Pa'l were found for the 182.5, 197.5 and 222.5 kPa isobars respectively. These observations collaborated well with the description of surface diffusion with permeation taking place in the Langmuir (strong adsorption) regime.
Permeation experiments through NaA as function of temperature were conducted for a 90 mol% steam -10 mol% hydrogen (90-10) binary mixture as well as for a 60-40 mixture of these two. At low temperatures the permeation of hydrogen was completely suppressed by the condensed steam resulting in an almost perfect separation. The Kelvin equation was used to estimate the pore size of the defects which was found to range between 1.86 and 2.45 nm. The temperature range over which these defects in the membrane were assumed to become unblocked (i.e. assuming when the first breakthrough of hydrogen occurred), were determined to be between 140 to 148 °c and between 128 to 130 °c for the 90-10 and 60-40 mixtures respectively. The mixture selectivities (towards water) between 115 °c and 130 °c were found to be immensely high (much greater than 1000) for both the 90-10 and 60-40 mixtures, while the ideal selectivities were calculated to be less than lover the same temperature range. At 140 °c, the selectivity towards water for the 9010 mixture was still greater than 1000; however for the 60-40 mixture at this temperature, an inversion of selectivity towards H2 had already taken place. The breakthrough in H2 permeance occurs at a much lower temperature when the feed mixture contains a lower concentration of water. Since the partial pressure of steam will be reduced, larger pores will become unblocked at lower temperatures according to the Kelvin equation. / Thesis (M. Ing. (Chemical Engineering))--North-West University, Potchefstroom Campus, 2008.
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Gas separation of steam and hydrogen mixtures using an α-alumina-Alumina supported NaA membrane / by S. MoodleyMoodley, Shawn January 2007 (has links)
In this study, the feasibility of a NaA zeolite membrane for the gas phase separation of steam and hydrogen mixtures was determined. The Fischer-Tropsch (FT) process, which produces high value fuels and chemicals from coal and natural gas, can be greatly improved upon by the selective removal of water from the FT reactor product stream. According to the FT reaction kinetics, the rate of reaction increases with the partial pressure of hydrogen but is adversely affected the presence of water in the reactor product stream. Chemisorbed water on the surface of the metal catalysts also enhances deactivation due to sintering and fouling. The use of a zeolite membrane reactor is well equipped to serve the purpose of in-situ water removal as it can facilitate the separation of chemical components from one another in the presence of catalytic reactions. The LTA type zeolite membrane NaA or zeolite 4A, in particular, is well suited for the separation of polar (H2O) from non-polar (H2) molecules because of its high hydrophilicity. NaA has also been identified as an excellent candidate for selective water removal applications due its high adsorption affinity and capacity for water.
The NaA membrane used in this study was manufactured by means of the in-situ crystallisation method where the growth of crystals on the inside surface of a centrifugally casted a-alumina support was favoured. Scanning electron microscopy (SEM) analyses performed on the membrane after a double hydrothermal synthesis indicated that the surface topology was rough and that the zeolite crystals formed were not uniform in size. Overall, the membrane thickness varied between 6.5 and 8.0 flm. An evaluation of the membrane quality was made possible through permeation experiments involving SF6 and Hz. The calculated Hz/SF6 permselectivity in this study was found to be 9.78, which despite being higher than the Knudsen diffusion selectivity of 8.54, confirmed the presence of intercrystalline defects or non-zeolitic pores in the membrane. Experiments concerning pure component and binary mixture permeation of steam and hydrogen through the supported NaA membrane were conducted over a temperature range of 115°C to 160 °c for binary hydrogen/steam mixtures, 25°C to 160°C for pure hydrogen and 130°C to 170°C for pure steam. For the permeation of pure component hydrogen, a local maximum in its permeance having a value of 224 x 10'°8 mol.m,z.s'!.Pa'! was reached at a system pressure and temperature of 6.875 bar and 75°C respectively. For the permeation of pure component steam
through NaA, the effects of capillary condensation in the pores and defects of the zeolite membrane resulted in a decrease in steam permeance as a function of absolute pressure for temperatures lower than 160 °c. Once the effects of capillary condensation had receded, maxima in the steam permeances as a function of temperature corresponding to values of 70 x 10,08, 65 X 10,08 and 75 x 10,08 mol.m•2.s'I.Pa'l were found for the 182.5, 197.5 and 222.5 kPa isobars respectively. These observations collaborated well with the description of surface diffusion with permeation taking place in the Langmuir (strong adsorption) regime.
Permeation experiments through NaA as function of temperature were conducted for a 90 mol% steam -10 mol% hydrogen (90-10) binary mixture as well as for a 60-40 mixture of these two. At low temperatures the permeation of hydrogen was completely suppressed by the condensed steam resulting in an almost perfect separation. The Kelvin equation was used to estimate the pore size of the defects which was found to range between 1.86 and 2.45 nm. The temperature range over which these defects in the membrane were assumed to become unblocked (i.e. assuming when the first breakthrough of hydrogen occurred), were determined to be between 140 to 148 °c and between 128 to 130 °c for the 90-10 and 60-40 mixtures respectively. The mixture selectivities (towards water) between 115 °c and 130 °c were found to be immensely high (much greater than 1000) for both the 90-10 and 60-40 mixtures, while the ideal selectivities were calculated to be less than lover the same temperature range. At 140 °c, the selectivity towards water for the 9010 mixture was still greater than 1000; however for the 60-40 mixture at this temperature, an inversion of selectivity towards H2 had already taken place. The breakthrough in H2 permeance occurs at a much lower temperature when the feed mixture contains a lower concentration of water. Since the partial pressure of steam will be reduced, larger pores will become unblocked at lower temperatures according to the Kelvin equation. / Thesis (M. Ing. (Chemical Engineering))--North-West University, Potchefstroom Campus, 2008.
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Matériaux innovants pour la rétention sélective de césium et de strontium à partir de solutions aqueuses multi-composants : synthèse, optimisation et évaluation des performances / Innovative materials for selective retention of cesium and strontium from aqueous multi-component solutions : synthesis, optimization and assessment of performanceAlby, Delhia 06 October 2017 (has links)
Ce travail porte sur la synthèse et la caractérisation de nouveaux matériaux afin de proposer une alternative dans le cadre de la dépollution nucléaire. Dans une première partie bibliographique, les principaux matériaux inorganiques utilisés pour ce procédé sont décrits en précisant leurs capacités de sorption. Les matériaux lamellaires apparaissent comme possédant un fort potentiel pour cette application. Deux solides ont retenu notre attention : les nanostructures à base de vanadates et de manganates.Des synthèses solvothermales sous flux micro-ondes de ces composés sont ensuite développées, afin d’obtenir une structuration sous forme de nanotubes de vanadates et de nanofleurs de manganates. Une optimisation des vanadates a ainsi été menée en évaluant l’impact de différents facteurs (par exemple, temps de maturation, temps de chauffage, nature et quantité de templates) sur les propriétés structurales et texturales des produits synthétisés. L’enroulement des feuillets est fortement influencé à la fois par la quantité d’amine et sa structure chimique. En effet, seules les amines à longue chaîne conduisent à l’obtention de nanotubes de façon homogène. Une analyse structurale a également été menée pour les deux types de composés en couplant les données expérimentales et celles obtenues par simulation.Les performances de sorption et la sélectivité des matériaux dans différents milieux (eau ultra-pure, eau de rivière) ont été évaluées vis-à-vis du césium et du strontium, seuls ou en mélange. Les résultats montrent clairement une sélectivité très forte des vanadates vis-à-vis du Cs+ et des manganates pour le Sr2+, même en milieu compétitif.La calorimétrie et la simulation moléculaire ont finalement été couplées pour mieux décrire les processus de sélectivité. / This work focuses on the synthesis and characterization of new nanostructured materials that can be potentially proposed as alternatives in the field of nuclear decontamination. The first part is devoted to the state of the art on the use of inorganic materials for decontamination purposes, with the emphasis placed on their sorption capacity and selectivity. The layer materials are considered as offering potential for such applications. In consequence, the main efforts in this work have been focused on manganate and vanadate nanostructures.Solvothermal synthesis of these materials was developed on the basis of micro-wave oven procedures to control the materials structuring, thus leading to vanadate nanotubes and manganate nanoflowers. The optimization of vanadates was carried out by taking into account the effect of various factors (e.g., duration of maturation and heating stages, nature and mass of the template) on both the structural and textural properties of the resulting substrates. It was demonstrated that the scrolling of the layers was strongly influenced by the amount of amine and its chemical structure. Indeed, only the amine templates possessing long chains allowed homogeneous nanotubes to be achieved. More information about the structuring process was inferred when coupling experimental and simulation approaches.The sorption performance of the resulting solid materials in terms of sorption capacity and selectivity was assessed in model and simulated systems obtained by using either ultrapure or river water with an adequate composition as solvent to prepare aqueous solutions of strontium or/and cesium. The results of sorption experiments clearly indicated strong selectivity of the vanadate structures toward Cs+ and that of the manganate ones toward Sr2+, even under conditions of competition among various ionic species.Direct calorimetry measurements of heat effects accompanying sorption were correlated with the results of molecular simulation studies to shed more light on the origin of the improved sorption selectivity.
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The use of synthesised USY as a dietary supplement for the removal of toxic metals (lead and cadmium) from simulated gastric juiceJaceni, Lydia Lucia January 2018 (has links)
Magister Scientiae (Medical Bioscience) - MSc(MBS) / The South African economy relies heavily on mining. The residues of these activities contain
harmful metals that are discharged into the environment as industrial wastes, contaminating
the air, soil, surface and ground water. A lot of people who live in remote areas in South Africa
rely on ground water to drink and cook. They also cultivate their own vegetables increasing the
risk of metal toxicity. Some of these metals are very toxic and can cause adverse effects upon
being ingested.
Toxic metals are well known to be harmful to humans. Some of these metals are carcinogenic
or nephrotoxic when a large amount is accumulated in the human body causing cancer and
destroying tissues such as the kidneys. The detrimental health effects of these metals may take
months to years before manifestation causing people to sideline them as hazards. One of the
major toxic elements that are discharged into the environment is lead.
A natural zeolite called clinoptilolite has been widely used as an adsorbent for toxic metals from
contaminated water and from the human body because of its properties such as ion-exchange
capacity and pore size. However, this natural zeolite clinoptilolite is not pure and may contain
traces of toxic elements of which the nature and concentration depend on the origin of
clinoptilolite. The structural stability of clinoptilolite in acidic or alkaline media is not well
documented. The lack of documented information about the leachates of clinoptilolite and
their long term effects on the human body may cause harm to people who ingest this zeolite.
This has led to investigation of synthetic zeolites such as faujasite which has already been used
for decontamination of sludge, industrial effluents and other waste water by removing toxic
metals such as Pb, Cd, Cu, Zn and As. This study focuses on comparing the toxic metal removal
efficiency of natural zeolite clinoptilolite (C), clinoptilolite-based faujasite (FAU3) and
clinoptilolite-based ultrastable Y zeolite (USY3), from contaminated water and simulated gastric
juice containing lead and cadmium and to evaluate the extent of leaching of other elements
from these zeolites.
Clinoptilolite was used as a starting material for the synthesis of faujasite (FAU3) which was
further treated with oxalic acid to get an ultrastable Y zeolite (USY3). Various techniques were
used to characterise the as-received clinoptilolite, faujasite zeolite and USY, namely XRD, SEMEDS,
FTIR, solid state NMR (27Al and 29Si) and BET-N2. These characterisation techniques
confirmed that clinoptilolite was successfully transformed into faujasite and that the treatment
of faujasite with oxalic acid yielded USY3. A comparative adsorption study was conducted using
three zeolite samples: namely Clinoptilolite (C), clinoptilolite-based faujasite (FAU3) and
ultrastable Y zeolite (USY3). ICP was used to characterise the liquid samples and it was
concluded that zeolites were efficient in removing lead and cadmium from contaminated water
samples as well as from simulated gastric juice. Some leachates from these zeolites were also
observed.
A contaminated water sample containing lead and cadmium was used as a medium where the
removal capacity and percentage removal with C, FAU3 and USY3 was investigated. It was
observed that the optimum dosage varied from one zeolite to the other and also from one
metal to the other. The optimum dosage for C, FAU3 and USY3 for the uptake of lead was found
to be 0.2 g, 0.2 g and 0.05 g respectively while for cadmium it was 0.4 g, 005 g and 0.1 g,
respectively. It was also shown in this study that the removal capacity for lead and cadmium
could be hindered by the Na content in FAU3 and USY3 due to the fact that these metals could
be in an uptake competition with Na and other cations that leached out or exchanged from the
zeolites. It was observed that the optimum metal concentration for lead uptake as well as for
cadmium with few metals being released back into the solution was 0.1 mg/L. The optimum
contact time for both lead and cadmium was 15 minutes. The factor that varied depending on
the type of metal was pH, which was at its optimum at 3.5 for lead and at 5.5 for cadmium.
A simulated gastric juice was contaminated with toxic metals (lead and cadmium) and the
zeolites were used to treat the contaminated samples. It was shown that the removal capacity
of these zeolites increased with the increase in initial concentration of the metal. Time proved
to be one factor that affected the behaviour of zeolites. The modification of the synthesised
faujasite into an ultrastable Y zeolite proved to have played a role in increasing the removal of
toxic metals and in preventing the high leaching of some elements out of the zeolite. / 2018-12-14
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Síntese de nanofios de óxidos semicondutores para aplicações em dispositivos ópticos e eletrônicos /Savu, Raluca. January 2009 (has links)
Resumo: A presente pesquisa teve como principal objetivo a obtenção de estruturas nanométricas de óxido de índio, óxido de estanho e óxido de zinco por evaporação térmica e síntese hidrotérmica e a construção e teste de sensores de gases e de fotodetectores de ultravioleta baseados nessas nanoestruturas. Foram realizados estudos da influência dos parâmetros experimentais das duas rotas de síntese usadas sobre as morfologias e as propriedades das estruturas. Para a obtenção das camadas nanoestruturadas por evaporação térmica foi especialmente construído um forno tubular que permitiu o controle da temperatura de deposição independente da temperatura de evaporação e da distância entre a fonte de evaporação e o substrato. Esses parâmetros, pouco explorados nas pesquisas reportadas na literatura, exerceram uma grande influência sobre a morfologia e as propriedades dos nanofios obtidos. O equipamento permitiu ainda um controle preciso da composição da atmosfera e da pressão de síntese. Na síntese química em solução, a construção de um reator hidrotérmico permitiu o estudo da influência da taxa de resfriamento sobre as dimensões, cristalinidade, morfologia e propriedades das nanoestruturas. Esse estudo, o primeiro do gênero na literatura, ressaltou a importância no controle deste parâmetro para sintetizar estruturas com propriedades melhoradas. As demais variáveis estudadas foram: a concentração das soluções, as camadas catalisadoras, a temperatura e o tempo de síntese. Foram testadas duas estratégias para a obtenção dos filmes nanoestruturados: spin-coating de suspensões de nanoestruturas sobre substratos de silício oxidado ou o crescimento das mesmas, durante a síntese, sobre substratos com camadas catalisadoras de zinco. Os nanofios e as camadas funcionais foram caracterizados por Difração de Raios-X (DRX), Microscopia Eletrônica de Varredura... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: The subject of this thesis covers the synthesis and growth of indium, tin and zinc oxide nanostructures by thermal evaporation and hydrothermal synthesis and the fabrication and testing of gas sensors and ultraviolet photodetectors based on these nanosized structures. For both chemical and physical routes, the influence of processing conditions over the morphology, dimensions and electrical properties of the nanowires was investigated. In order to obtain nanostructured layers by thermal evaporation a tubular furnace was specifically builti, allowed the control of the source-substrate distance and the deposition temperature independently of the evaporation one. These parameters, slightly explored in the literature, granted a big influence over the nanowires morphology and properties. Moreover, the equipment permitted the control of deposition atmosphere and pressure. The design and assembly of a hydrothermal reactor allowed studying the influence of the cooling rate over the dimension, morphology, cristallinity and, consequently, the properties of the nanostructures. This study highlighted the importance of controlling this particular parameter in the hydrothermal process, yielding nanostructured materials with enhanced properties. Variables such as solution concentration, synthesis temperature and time, surfanctants and precursors were also explored in the hydrothermal process. In order to obtain nanostructured thin films using the chemical bath deposition, two processing techniques were employed: spin-coating of powder suspensions over oxidized silicon substrates and nanostructured anisotropic growth directly from solution using zinc coated substrates. The nanowires and the functional nanostructured layers were characterized by X-Ray Diffraction (XRD), Field Emission Scanning Electron Microscopy (FE - SEM), Transmission Electron Microscopy (TEM) and X-ray Photoelectron Spectroscopy (XPS)... (Complete abstract click electronic access below) / Orientador: Maria Aparecida Zaghete Bertochi / Coorientador: Elson Longo / Banca: Antonio Ricardo Zanatta / Banca: Mônica Alonso Cotta / Banca: Talita Mazon Anselmo / Banca: Sidney José Lima Ribeiro / O Programa de Pós-Graduação em Ciência e Tecnologia de Materiais, PosMat, tem caráter institucional e integra as atividades de pesquisa em materiais de diversos campi da Unesp / Doutor
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