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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Synthesis and characterization of nanocatalysts for applications in water purification and hydrogen production.

Popat, Yaksh Jyotindra 12 December 2019 (has links)
The thesis focuses on synthesis and characterization of nanocatalysts for applications in wastewater treatment and hydrogen production through electrochemical water splitting. Different photocatalysts and electrocatalysts are synthesized using wet chemistry techniques as well as Pulsed Laser Deposition (PLD). The synthesized catalysts pave demonstrate excellent catalytic activity thereby paving way for their use on an industrial scale.
2

Gold and gold-palladium branched nanocrystals for applications in plasmonic catalysis and electrocatalysis / Nanocristais ramificados de ouro e ouro-paládio para aplicações em catálise e eletrocatálise plasmônica

Silveira, Vitor Renato Ribeiro 28 January 2019 (has links)
The harvesting of solar light is one of the main challenges in science. The outstanding optical properties of plasmonic in the visible and near-infrared ranges due to the localized surface plasmon resonance (SPR) has emerged as a promising approach for the solar-tochemical energy conversion. Specifically, it has been demonstrated that the SPR excitation in the visible range in silver (Ag) and gold (Au) nanoparticles can drive and accelerate chemical transformations. This field, coined plasmonic catalysis, enables one to merge catalytic and optical properties in the nanoscale and use visible or near-infrared light as a sustainable energy input to accelerate molecular transformations. In the first part of this thesis. we developed Au branched nanostructures to be employed as plasmonic catalysts. In this case, we aimed at investigating the effect of the sharp tips at their surface over their plasmonic catalytic performance, as it is established that tips can concentrate higher electric field enhancements relative to rounded surfaces as a result of the lightning rod effect, which, in turn, can translate into higher plasmonic catalytic performances. Here, the plasmonic-catalytic performances were tested using the SPR mediated oxidation of paminothiophenol and benzylamine as model transformations. While the Ag and Au nanoparticles support LSPR excitation in the visible and near-infrared ranges, their catalytic properties are limited in terms of versatility. Conversely, metals that are important in catalysis, such as palladium Pd, do not support SPR excitation in the visible or near-infrared range. In the second part of this thesis, we developed multimetallic nanoparticle morphologies, composed of both Au and Pd, that enabled us to marry catalytic and plasmonic component in order to address this challenge. We focused on plasmonic core-catalytic shell structures, in which the shell displayed a branched morphology. Parameters such as shell thickness could be controlled, and structure performance relationships were established towards the methanol electro-oxidation under plasmonic excitation. / O aproveitamento da luz solar é um dos principais desafios da ciência. As excepcionais propriedades óticas plasmônicas nas regiões do visível e do infravermelho próximo, devido a ressonância plasmônica de superfície localizada (SPR), surgiram como uma abordagem promissora para conversão de energia solar em energia química. De maneira mais específica, vem sendo demonstrado que a excitação SPR na região do visível em nanopartículas de prata (Ag) e ouro (Au) podem conduzir e acelerar transformações químicas. Esse campo, chamado catálise plasmônica, permite a fusão de propriedades óticas e catalíticas na nanoescala e a utilização de luz visível ou infravermelha próxima como uma fonte de energia para acelerar transformações moleculares. Na primeira parte desta dissertação, nós desenvolvemos nanoestruturas de ouro ramificadas para serem empregadas em catálise plasmônica. Neste caso, nosso foco era investigar o efeito de pontas afiadas em sua superfície sobre seu desempenho catalítico plasmônico, visto que está bem estabelecido que pontas podem concentrar maiores intensificações de campo elétrico em relação a superfícies arredondadas como resultado do \"efeito para-raios\" o que, por sua vez, pode se traduzir em maiores desempenhos em catálise plasmônica. O desempenho da catálise plasmônica foi testado através da oxidação mediada por SPR do p-aminotiofenol e da benzilamina como reações modelo. Contudo, enquanto nanopartículas de prata e ouro apresentam excitação SPR nas regiões do visível e infravermelho próximo, suas propriedades catalíticas são limitadas em termos de versatilidade. Por outro lado, metais que são importantes em catálise, como o paládio, não apresentam excitação SPR no visível e infravermelho próximo. Por isso, na segunda parte desta dissertação, nós desenvolvemos nanopartículas multimetálicas, compostas de Au e Pd, que nos permitem unir os componentes catalíticos e plasmônicos com o objetivo de enfrentar este desafio. Nós focamos em estruturas do tipo core-shell, com núcleos plasmônicos e cascas catalíticas, na qual a casca apresenta morfologia ramificada. Paramêtros como a espessura da casca puderam ser controlados, e a relação estruturaperformance foi estabelecida através da eletro-oxidação do metanol sobre excitação plasmônica.
3

Tio₂nanocatalysts: synthesis, layer-by-layer immobilisation on glass slides and their support on carbon-covered alumina (cca) for application in drinking water treatment

16 August 2012 (has links)
D.Phil. / Clean water (i.e. water that is free of toxic chemicals and pathogens) is essential to human health and in South Africa the demand is fast exceeding the supply. The prevalence of toxic contaminants in water remains a huge challenge for water supplying companies and municipalities. However, the presently used water treatment technologies either fail to remove these contaminants to acceptable levels or they transform them into more toxic substances (e.g., DBPs). Nanocatalysts, especially TiO2 (titania) have a proven potential to treat ‘difficult-to-remove’ contaminants and hence are expected to play an important role in solving many serious environmental and pollution challenges. In this study TiO2 nanocatalysts were used for the degradation of Rhodamine B dye both under UV and visible light irradiation. Two phases of titania, i.e. anatase and rutile phases, were compared for the degradation of Rhodamine B under UV light irradiation. The anatase titania was found to be more photocatalytically active for the degradation of Rhodamine B than the rutile phase. It completely degraded 100 mg ℓ–1 (100 mℓ) of Rhodamine B within 270 min and was two times more photocatalytically active than the rutile phase (Kapp of 0.017 min–1 compared to 0.0089 min–1). To extend the band edge of the titania nanocatalysts towards visible-light, TiO2 was doped with metal ions (Ag, Co, Ni and Pd). These metal-ion-doped titania nanocatalysts were photocatalytically active under visible-light illumination. The Pd-doped titania had the highest photodegradation efficiencies, followed by Ag-doped and Co-doped, while Ni-doped had the lowest. The optimum metal-ion loading percentage was found to be at 0.4%, with the exception of Co-doped titania as it had the highest efficiencies at 1% loadings. The free and metal-ion-doped titania nanocatalysts were embedded on carbon-covered alumina (CCA) supports. The CCA-supported TiO2 nanocatalysts were more photocatalytically active under visible light illumination than they were under UV-light irradiation. The CCA-supported metal-ion-doped titania nanocatalysts were more photocatalytically active under visible light than their unsupported counterparts. The CCA-supported Pd-TiO2 nanocatalysts were the most active while CCA-supported Ni-TiO2 catalysts were the least active. The improved photocatalytic activities observed were as a result of increased surface areas of the CCA-supported nanocatalysts. Also, supporting the nanocatalysts did not destroy the anatase phase of the titania while doping with metal ions and supporting on CCAs resulted in decreased band gap energies, hence the visible-light photocatalytic activities. Finally, the metal-ion-doped titania nanocatalysts were supported on glass slides using the layer-by-layer thin film self-assembly technique. This was to overcome the aggregation and post treatment problems associated with the use of TiO2 in suspension form. PAH and PSS were the polyelectrolytes used. These metal-ion-doped titania thin films were highly porous and strongly adhered by the polyelectrolytes onto the glass slides. The thin films were photocatalytically active for the degradation of Rhodamine B under visible light irradiation. The photocatalytic degradation efficiencies observed were similar for all four metal-ions (i.e. Ag, Co, Ni and Pd) with average degradation of 30%, 50%, 70% and 90% for 5 catalysts (5 glass slides) of 1, 3, 5 and 10 bi-layers, respectively, after 330 min. Although, these were less active than the suspended titania nanocatalysts, this study proved as a stepping stone towards large scale use of titania nanocatalysts using solar energy as the irradiation source. Also, catalyst reusability studies were performed and the PAH/PSS m-TiO2 thin films were found to be highly stable over the five cycles it was tested for.
4

Nanoestruturas bimetálicas e ocas: controlando forma, composição, e estrutura para aplicações em catálise / Bimetalli and hollew nanostructures: controlling shape, composition, and structure for catalytic applications

Wendler, Alexandra Macedo 09 September 2016 (has links)
Essa tese visa o desenvolvimento de metodologias simples, eficazes, versáteis e ambientalmente amigáveis para se obter nanomateriais metálicos com controle fino sobre sua forma, composição e estrutura (interior sólido ou vazio) para aplicações em catálise. Em especial, temos interesse no desenvolvimento de nanoestruturas ocas esféricas (nanocascas) compostas por prata-ouro (AgAu), prata-paládio (AgPd) e prata platina (AgPt). Essas nanocascas foram obtidas através da reação de substituição galvânica entre esferas de Ag e íons AuCl4-, PdCl42- ou PtCl62-, respectivamente. Como a reação de substituição galvânica permite não apenas o controle sobre a composição destes sistemas, mas também a obtenção de interiores vazios, esta estratégia representa uma alternativa promissora para a obtenção de nanomateriais apresentando características controláveis e atrativas para aplicações catalíticas. Diante dessas qualidades, esse projeto focou em aplicações para reações orgânicas de redução e acoplamento. Foi realizada uma investigação, de maneira sistemática, como a estrutura e composição dos nanomateriais metálicos produzidos influenciam a sua atividade catalítica, mostando que as atividades foram fortemente dependentes da composição e estrutura, abrindo a possibilidade para o planejamento de nanocatalisadores com atividades catalíticas controladas para uma transformação de interesse. / This thesis aims at developing facile, efficient, versatile, and environmentally friendly methodologies to obtain metallic nanomaterials with controlled shapes, compositions and structure (solid or hollow interiors) for applications in catalysis. In particular, we focused on hollow nanospheres (nanoshells) composed of silver-gold (AgAu), silver-palladium (AgPd), and silver-platinum (AgPt). These nanoshells were obtained by galvanic replacement reaction between Ag nanosphere and AuCl4-, PdCl42- or PtCl62-, respectively. The galvanic replacement reaction not only allows control over the composition of these systems, but also to obtain hollow interiors. Therefore, this strategy is a very promising alternative for obtaining nanomaterials with controllable features attractive for catalytic applications. In this case, we investigated applications towards reduction and coupling transformations. A systematic investigation was carried out regarding how the structures and compositions of the produced nanoshells influenced their catalytic performance. Our results showed that the activities were strongly dependent on the composition and structure, opening a range of possibility for designing nanocatalysts with desired catalytic activities for a target transformation.
5

Nanoestruturas bimetálicas e ocas: controlando forma, composição, e estrutura para aplicações em catálise / Bimetalli and hollew nanostructures: controlling shape, composition, and structure for catalytic applications

Alexandra Macedo Wendler 09 September 2016 (has links)
Essa tese visa o desenvolvimento de metodologias simples, eficazes, versáteis e ambientalmente amigáveis para se obter nanomateriais metálicos com controle fino sobre sua forma, composição e estrutura (interior sólido ou vazio) para aplicações em catálise. Em especial, temos interesse no desenvolvimento de nanoestruturas ocas esféricas (nanocascas) compostas por prata-ouro (AgAu), prata-paládio (AgPd) e prata platina (AgPt). Essas nanocascas foram obtidas através da reação de substituição galvânica entre esferas de Ag e íons AuCl4-, PdCl42- ou PtCl62-, respectivamente. Como a reação de substituição galvânica permite não apenas o controle sobre a composição destes sistemas, mas também a obtenção de interiores vazios, esta estratégia representa uma alternativa promissora para a obtenção de nanomateriais apresentando características controláveis e atrativas para aplicações catalíticas. Diante dessas qualidades, esse projeto focou em aplicações para reações orgânicas de redução e acoplamento. Foi realizada uma investigação, de maneira sistemática, como a estrutura e composição dos nanomateriais metálicos produzidos influenciam a sua atividade catalítica, mostando que as atividades foram fortemente dependentes da composição e estrutura, abrindo a possibilidade para o planejamento de nanocatalisadores com atividades catalíticas controladas para uma transformação de interesse. / This thesis aims at developing facile, efficient, versatile, and environmentally friendly methodologies to obtain metallic nanomaterials with controlled shapes, compositions and structure (solid or hollow interiors) for applications in catalysis. In particular, we focused on hollow nanospheres (nanoshells) composed of silver-gold (AgAu), silver-palladium (AgPd), and silver-platinum (AgPt). These nanoshells were obtained by galvanic replacement reaction between Ag nanosphere and AuCl4-, PdCl42- or PtCl62-, respectively. The galvanic replacement reaction not only allows control over the composition of these systems, but also to obtain hollow interiors. Therefore, this strategy is a very promising alternative for obtaining nanomaterials with controllable features attractive for catalytic applications. In this case, we investigated applications towards reduction and coupling transformations. A systematic investigation was carried out regarding how the structures and compositions of the produced nanoshells influenced their catalytic performance. Our results showed that the activities were strongly dependent on the composition and structure, opening a range of possibility for designing nanocatalysts with desired catalytic activities for a target transformation.
6

Size, Shape and Support Effects on the Catalytic Activity of Immobilized Nanoparticles

Ghadamgahi, Sedigheh January 2014 (has links)
Abstract: A brief overview of this PhD thesis, The emergence of nanotechnology has stimulated both fundamental and industrially relevant studies of the catalytic activity of noble metal nanoparticles. Palladium, ruthenium and gold are well known catalysts when used in nanoparticle- based systems. This body of work endeavoured to investigate the catalytic activity of these noble metal nanoparticles through three studies as a briefly overviewed below. Study 1: Palladium is a well-known catalyst, even in bulk phases, but its high cost had driven industry towards its use in nanoparticle- based systems well before nanotechnology had attracted the attention of the media. Palladium nanoparticles often show remarkable catalytic activity and selectivity, particularly for the hydrogenation of some unsaturated hydrocarbons, such as alkenes, alkynes and unsaturated carbonyl compounds. The nature of supports can affect the catalytic activity and selectivity of metal-support interaction. Natural polymeric supports, such as wool, can be suitable for new generation of composite materials incorporating nanosized metal nanoparticles and have the added advantage of being “environmentally friendly”. Catalytic hydrogenation of cyclohexene to cyclohexane by palladium nanoparticles immobilized on wool was demonstrated by using a Parr high pressure hydrogenation set-up. The efficiency of the process was explored over loading rates from 1.6% to 2.6% of palladium nanoparticles (by weight) with a variety of particle sizes. Optimization of the reaction conditions including, stirring rate, amounts of reactants, gas pressure and target temperature, led to series of catalytic activity tests carried out for 5 or 24 hours (each) at 400psi H2 and 40 oC using a stirring rate 750 rpm. Product mixtures were analysed using gas chromatography (GC-FID) to determine conversions. Samples S1 and S2 proved to be the most active catalysts because the average Pd particle size was around ~5 nm and the particles were more accessible for the reactant (i.e., Pd particles were on the surface of wool). However, under the catalytic testing conditions studied, wool (Pd/wool) did not show advantages over commercially used palladium nanoparticles on activated carbon (Pd/C). Study 2: Ruthenium fabricated as noble metal nanoparticles can be catalytically active for hydrogenation of organic compounds. However, a challenging issue for researchers is that Ru nanocatalysts can be spontaneously deactivated due to effects, such as sintering or leaching of active components, oxidation of noble metal nanoparticles, inactive metal or metal oxide deposition and impurities in solvents and reagents. Calcination of noble metal nanoparticles is one option for reactivation of Ru nanoparticles immobilized on SiO2 (Ru/SiO2) utilized as nanocatalysts in chemical reactions. In fact, the catalytic activity of noble metal nanoparticles is known to be proportional to the active part of the surface area. The effects of calcinations on catalytic activity of “shape- specific” 0.1 wt% Ru/SiO2 for hydrogenation of cyclohexene to cyclohexane were investigated. Optimization of calcinations by varying temperature and time proved to be effective on the activity of nanocatalysts retaining the Ru nanocatalysts shapes for the hydrogenation of cyclohexene. Product mixtures were analysed using gas chromatography (GC-FID) to determine conversions. The Ru catalysts showed the highest activity (100%) when they were activated by calcination following protocol No.1 in a furnace under the mildest reductive conditions studied (temperature = 200 oC for 1 hour, which was the shortest calcination time). HRTEM study showed only minor deformation of the Ru nanoparticles and minimal aggregation for this type of activation. Study 3: Supported gold nanoparticles have excited much interest owing to their unusual and somewhat unexpected catalytic activity particularly with the selective oxidation of organic compounds. Gold nanoparticles immobilized on Norit activated carbon (Au101/C) via colloidal deposition gave high selectivity of benzyl alcohol oxidation. The presence of a base (K2CO3) increased the catalytic activity of gold nanocatalysts (which was negligible in the absence of base) through dehydrogenation of the alcohol via deprotonation of a primary OH groups, and helped overcome the rate-limitation step of the oxidation process. The interaction between the gold species and the support was investigated by measuring change in catalytic activity with different activation methods (i.e., washing with a solvent at elevated temperature, and/or followed by calcinations). A mixture of benzyl alcohol as a reactant, methanol as a solvent, K2CO3 as a base and oxygen gas was studied by the activated gold nanocatalysts using a mini reactor set-up. The efficiency of the process was explored by varying the amounts of benzyl alcohol and the base, target temperature, metal loading of the gold catalysts rate and the solvent, between 3 and 24 hours at 73 psi O2 and a stirring rate (750 rpm). The samples of the reaction mixture were centrifuged and analysed by highperformance liquid chromatography (HPLC) to determine conversions. The effect of size on the catalytic activity was studied for different types of gold particles (Au101, Aunaked and Aucitrate) and clusters (Au8 and Au9) immobilized on powder Norit activated carbon. The highest activity of benzyl alcohol oxidation was observed for activated 1.0 wt% Au101/C catalysts (washed with toluene and followed by calcination under vacuum at 100 oC for 3 h) for ~3.5 nm gold particles. Additionally, the support effect was studied for gold particles immobilized on different types of carbons, such as Norit activated carbon (powder, granular and powdered) and mesoporous carbons (CMK-3, CMK-8 and NCCR-41), granular modified carbon (–SH and –SO3H groups) and Vulcan carbon. The highest activity was observed by activated 1.0 wt% Au101/C8 catalysts (washed with toluene and followed by calcination under vacuum at 100 oC for 3 h). Activated 1% Au101/C41 (washed with toluene followed by calcination under vacuum at 100 oC for 3 hours) with 2.6 ± 0.1 nm gold particle size showed the highest selectivity towards methyl benzoate as a main product (S%: 88%) after 3 hours reaction time. However, activated 1% Au101/C (calcination in O2 -H2 at 100 oC for 3 hours) with 6.6 ± 0.3 nm gold particle size exhibited the highest selectivity towards benzoic acid as a main product (S: 86%) after 24 hours reaction time.Therefore, particle size and type of carbon support can be considered as playing crucial roles in defining the catalytic activity of gold nanocatalysts which were used for benzyl alcohol oxidation.
7

Organic Matter Occurrence in Arizona and Innovative Treatment by Granular Activated Carbon

January 2012 (has links)
abstract: Population growth and fresh water depletion challenge drinking water utilities. Surface water quality is impacted significantly by climate variability, human activities, and extreme events like natural disasters. Dissolved organic carbon (DOC) is an important water quality index and the precursor of disinfection by-products (DBPs) that varies with both hydrologic and anthropogenic factors. Granular activated carbon (GAC) is a best available technology for utilities to meet Stage 2 D/DBP rule compliance and to remove contaminants of emerging concern (CECs) (e.g., pharmaceutical, personal care products (PCPs), etc.). Utilities can operate GAC with more efficient and flexible strategies with the understanding of organic occurrence in source water and a model capable predicting DOC occurrence. In this dissertation, it was found that DOC loading significantly correlated with spring runoff and was intensified by dry-duration antecedent to first flush. Dynamic modeling based on reservoir management (e.g., pump-back operation) was established to simulate the DOC transport in the reservoir system. Additionally, summer water recreational activities were found to raise the level of PCPs, especially skin-applied products, in raw waters. GAC was examined in this dissertation for both carbonaceous and emerging nitrogenous DBP (N-DBP) precursors (i.e., dissolved organic nitrogen (DON)) removal. Based on the experimental findings, GAC preferentially removes UV254-absorbing material, and DOC is preferentially removed over DON which may be composed primarily of hydrophilic organic and results in the low affinity for adsorption by GAC. The presence of organic nitrogen can elevate the toxicity of DBPs by forming N-DBPs, and this could be a major drawback for facilities considering installation of a GAC adsorber owing to the poor removal efficiency of DON by GAC. A modeling approach was established for predicting DOC and DON breakthrough during GAC operation. However, installation of GAC adsorber is a burden for utilities with respect to operational and maintenance cost. It is common for utilities to regenerate saturated GAC in order to save the cost of purchasing fresh GAC. The traditional thermal regeneration technology for saturated GAC is an energy intensive process requiring high temperature of incineration. Additionally, small water treatment sites usually ship saturated GAC to specialized facilities for regeneration increasing the already significant carbon footprint of thermal regeneration. An innovative GAC regeneration technique was investigated in this dissertation for the feasibility as on-site water treatment process. Virgin GAC was first saturated by organic contaminant then regenerated in-situ by iron oxide nanocatalysts mixed with hydrogen peroxide. At least 70 % of adsorption capacity of GAC can be regenerated repeatedly for experiments using modeling compound (phenol) or natural organic matter (Suwannee River humic acid). The regeneration efficiency increases with increasing adsorbate concentration. Used-iron nanocatalysts can be recovered repeatedly without significant loss of catalytic ability. This in-situ regeneration technique provides cost and energy efficient solution for water utilities considering GAC installation. Overall, patterns were found for DOC and CEC variations in drinking water sources. Increasing concentrations of bulk (DOC and DON) and/or trace organics challenge GAC operation in utilities that have limited numbers of bed-volume treated before regeneration is required. In-situ regeneration using iron nanocatalysts and hydrogen peroxide provides utilities an alternative energy-efficient operation mode when considering installation of GAC adsorber. / Dissertation/Thesis / Ph.D. Civil and Environmental Engineering 2012
8

ELECTROCHEMICAL/ELECTROFLOTATION PROCESS FOR DYE WASTEWATER TREATMENT

Butler, Erick 08 August 2013 (has links)
No description available.
9

Metal Oxide Graphene Nanocomposites for Organic and Heavy Metal Remediation

Alam, Tanvir E 01 January 2012 (has links)
This thesis consists of two research problems in the water decontamination area. In the first work, the main focus is to understand the structure and photocatalytic activity of titanium dioxide with graphene (G-TiO2) which is synthesized by using sol-gel method. The photocatalytic activity of TiO2 is limited by the short electron hole pair recombination time. Graphene, with high specific surface area and unique electronic properties, can be used as a good support for TiO2 to enhance the photocatalytic activity. The obtained G-TiO2 photocatalysts has been characterized by X-Ray Diffraction (XRD), Raman Spectroscopy, Transmission Electron Microscopy (TEM), FTIR Spectroscopy and Ultraviolet visible (UV-vis) Spectroscopy. This prepared G-TiO2 nanocomposite exhibited excellent photocatalysis degradation on methyl orange (MO) under irradiation of simulated sunlight. Such enthralling photocatalyst may find substantial applications in various fields. The primary objective of the second work is to understand the nanocomposite structure of SiO2 coated over graphene (G) nanoplatelets. An attempt has been made to synthesize G-SiO2 nanocomposite using sol-gel technique. The G-SiO2 nanocomposite is characterized using Scanning Electron Microscopy (SEM), Transmission Electron Microscopy (TEM), Raman spectroscopy, FTIR spectroscopy, and Electrochemical and Electrical measurement technique, respectively. In this work, G-SiO2 nanoparticles with the water containing salts of zinc is added, and allowed to settle in water. The ZnCl2 ix concentration displays a whitish color solution which has turned to colorless within one or two hours of treatment with G-SiO2 nanocomposites. The presence of heavy metal is tested using electrochemical cyclic voltammetry (CV) technique. The CV measurement on the water treated with G-SiO2 has been tested for several days to understand the presence of heavy metals in water. Interestingly, the near complete separation has been observed by treating the heavy metal contaminated water sample for one to two days in presence of G-SiO2 nanoparticles. The redox potential observed for the heavy metal has been found to diminish as a function of treatment with respect to time, and no redox peak is observed after the treatment for four to five days. Further test using EDS measurement indicates that the heavy metal ions are observed within the G-SiO2 nanocomposite. The recovery of G-SiO2 nanocomposite is obtained by washing using deionized water. Our experimental finding indicates that the G-SiO2 nanocomposite could be exploited for potential heavy metals cleaning from waste or drinking water.
10

Relation between surface structural and chemical properties of platinum nanoparticles and their catalytic activity in the decomposition of hydrogen peroxide

Serra Maia, Rui Filipe 26 September 2018 (has links)
The disproportionation of H₂O₂ to H₂O and molecular O₂ catalyzed by platinum nanocatalysts is technologically very important in several energy conversion technologies, such as steam propellant thrust applications and hydrogen fuel cells. However, the mechanism of H₂O₂ decomposition on platinum has been unresolved for more than 100 years and the kinetics of this reaction were poorly understood. Our goal was to quantify the effect of reaction conditions and catalyst properties on the decomposition of H₂O₂ by platinum nanocatalysts and determine the mechanism and rate-limiting step of the reaction. To this end, we have characterized two commercial platinum nanocatalysts, known as platinum black and platinum nanopowder, and studied the effect of different reaction conditions on their rates of H₂O₂ decomposition. These samples have different particle size and surface chemisorbed oxygen abundance, which were varied further by pretreating both samples at variable conditions. The rate of H₂O₂ decomposition was studied systematically as a function of H₂O₂ concentration, pH, temperature, particle size and surface chemisorbed oxygen abundance. The mechanism of H₂O₂ decomposition on platinum proceeds via two cyclic oxidation-reduction steps. Step 1 is the rate limiting step of the reaction. Step 1: Pt + H₂O₂ → H₂O + Pt(O). Step 2: Pt(O) + H₂O₂ → Pt + O₂ + H₂O. Overall: 2 H₂O₂ → O₂ + 2 H₂O. The decomposition of H₂O₂ on platinum follows 1st order kinetics in terms of H₂O₂ concentration. The effect of pH is small, yet statistically significant. The rate constant of step 2 is 13 times higher than that of step 1. Incorporation of chemisorbed oxygen at the nanocatalyst surface resulted in higher initial rate of H₂O₂ decomposition because more sites initiate their cyclic process in the faster step of the reaction. Particle size does not affect the kinetics of the reaction. This new molecular-scale understanding of the decomposition of H₂O₂ by platinum is expected to help advance many energy technologies that depend on the rate of H₂O₂ decomposition on nanocatalysts of platinum and other metals. / Ph. D. / Platinum nanomaterials are indispensable to catalyze a variety of industrial and technological processes ranging from catalytic conversion of carbon monoxide (CO), hydrocarbons, and nitrogen oxides (NO<sub>x</sub>) in modern automobiles to energy production by hydrogen fuel cells and thrust generation in steam propellers. These technological innovations have a tremendous impact in modern society, including the areas of transportation, energy supply, soil and water quality, environmental remediation and global climate change. The decomposition of hydrogen peroxide (H₂O₂) to water (H₂O) and oxygen (O₂) on platinum nanomaterials is of particular importance because it affects the efficacy of many technological applications, such as hydrogen peroxide steam propellers and hydrogen fuel cells. However, the reaction pathway and kinetics of H₂O₂ decomposition on platinum were only partly understood. My goal was to understand how the reaction conditions and the nanocatalyst properties control the mechanism and kinetics of platinum-catalyzed hydrogen peroxide decomposition. To do that we characterized the atomic scale structural and chemical properties of two different platinum nanocatalysts, known as platinum black and platinum nanopowder and evaluated the effect of their properties in their catalytic activity. Our characterization studies were used to understand the reactivity of these two platinum nanocatalysts in the decomposition of H₂O₂, which we evaluated separately in laboratory studies. Establishing relationships between the catalyst properties and their activity, as we have done in this work for platinum nanocatalysts in the decomposition of hydrogen peroxide, has the potential to improve nanocatalyst design and performance for those applications.

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