Nanocompostos a base de cério com aplicações na absorção da radiação ultravioleta / Cerium-based nanocompounds for UV light absorption application

Lima, Juliana Fonseca de

01 March 2013

Luz e oxigênio induzem reações de degradação (foto-oxidação) que modificam as propriedades físicas e químicas da matéria, efeitos nocivos da radiação ultravioleta (UV) podem causar descoloração de corantes e pigmentos, amarelamento de plásticos, perda de brilho e da propriedade mecânica (cracking) de materiais, queimaduras, câncer de pele, entre outros problemas relacionados à luz UV. A fim de reduzir os efeitos nocivos da radiação UV e alcançar uma adequada conservação das propriedades dos materiais surgem os absorvedores ou filtros UV. Uma vez que materiais nanométricos a base de cério apresentam atividade fotocatalítica menor e elevada absorção na região do UV tornam-se filtros solares com aplicabilidade em diversas áreas quando comparados aos óxidos utilizados atualmente com função de filtros solares (ZnO e TiO2). Fosfatos de cério (III) (CePO4) foram preparados por Pechini (modificado), síntese hidrotermal e microemulsão reversa; as amostras foram submetidas a tratamento térmico em distintas temperaturas com o intuito de averiguar a estrutura do CePO4 e influência desta na capacidade da absorção UV. Sistemas de óxidos metálicos contendo cério também foram estudados, sendo sintetizados por sol-gel não-alcoóxido e aplicados na forma de pó e filme fino sobre substrato de vidro. A preocupação com a morfologia e o tamanho dos materiais motivou a escolha pelas metodologias de síntese empregadas. Neste trabalho foram exploradas e elucidadas as propriedades dos materiais a base de cério em absorver luz UV, devido às transições 4f-5d dos íons Ce3+ e/ou às transições entre banda de condução e banda de valência. As amostras foram analisadas por espectroscopia de absorção no UV-Vis e na região do infravermelho (FTIR), difração de raios X (XRD), difração de elétrons, susceptibilidade magnética (MS), microscopia eletrônica de varredura (SEM), microscopia eletrônica de transmissão (TEM), espectroscopia de reflectância difusa (DRS), atividade fotocatalítica (AF) e ressonância paramagnética de elétrons (EPR). As excelentes propriedades morfológicas, ópticas e fotocatalíticas indicam a possível aplicação dos materiais à base de cério, foco de investigação do presente trabalho, como filtros solares em proteção cosmetológica (cremes, shampoos, sprays etc) ou de materiais (tintas, vernizes, vidros e outros). / Light and oxygen induce degradation reactions (photo-oxidation) that modify the physical and chemical properties of the matter. The damaging UV radiation is responsible for the discoloration of dyes and pigments, weathering, yellowing of plastics, loss of gloss and mechanical properties (cracking), sunburnt skin and other problems associated to UV light. UV absorbers or UV filters have been used in order to reduce these damaging effects and achieve an adequate conservation of the properties of the materials. In front of this problem, cerium based nanomaterials are promising inorganic UV absorbers for the substitution of zinc and titanium oxide, once it presents high UV absorptivity, a lower refraction index than TiO2 and ZnO, and a higher chemical inertia (and thus a lower photocatalytic activity). Nanostructured cerium phosphates (CePO4) were prepared by Pechini, hydrothermal and reverse microemulsion synthesis, and some parameters (calcinations temperature and reactants rate) employed in each synthesis were investigated. Cerium metal oxide systems synthesized by sol-gel (non-alcooxide) and applied as powder and thin films materials were investigated too. The methodology of the synthesis were chosen aiming ideal morphology and particles size. In this work we explored and elucidated the properties of UV absorber cerium based nanomaterials , due to 4f-5d transitions of Ce3+ ions, charge transference of Ce4+ and, a little portion is due to the contribution of valence and conduction band. The samples were characterized by UV-Vis absorption spectroscopy , Fourier transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), electron diffraction, magnetic susceptibility (MS), scanning electron microscopy (SEM), transmission electron microscopy (TEM), diffuse reflectance spectroscopy (DRS), photocatalytic activity (PA) and electron paramagnetic resonance (EPR). The excellent morphological, optical and photocatalytic properties indicate the possible application of cerium based materials in solar protection for cosmetics (creams, shampoos, sprays etc.) or materials (paints, varnishes, glass and others).

Cério

Cerium

Fotoproteção.

Nanomateriais

Nanomaterials

Photoprotection

Radiação Ultravioleta

Rare Earth

Terras Raras

Utraviolet radiation

Nanomatériaux multifontionnels à base de terre rare et de métalde transition : propriétés structurales, magnétiques etmagnétocaloriques / Multifunctional nanomaterials based on rare earth and transition metal : structural, magnetic and magnetocaloric properties

Bouzidi, Wassim

20 December 2018

Les matériaux nanostructurés multifonctionnels à base de terre rare (R) et métal de transition (T) présentent un intérêt croissant dans la recherche scientifique. Le développement de cet axe est basé sur la maitrise de la structure fondamentale et le comportement de la matière à l’échelle nanométrique. Dans ce travail, nous nous sommes intéressés aux alliages Pr5Co19, leurs dérivés carburés et hydrurés. Ce système cristallise dans la structure rhomboédrique de type Ce5Co19 de groupe d’espace R-3m. Le composé Pr5Co19 présente une transition magnétique de l’état ferromagnétique à l’état paramagnétique à 690 K. Une anisotropie uniaxiale avec un champ coercitif de l’ordre de 1.5 T ont été enregistrés à la température ambiante.Par ailleurs, Nous avons observé que l’insertion d’un élément léger tel que le carbone ou l’hydrogène est un moyen efficace permettant d’augmenter la température de Curie par rapport au composé parent. Les nanomatériaux, de formule générale Pr5Co19Hx, présentent des cycles d’absorption et désorption réversibles, avec une capacité d’absorption de l’hydrogène égale à 12H/f.u, soit 0.5 hydrogène par maille (H/M) au total.Parallèlement, nous nous sommes intéressés à l’étude de l’effet magnétocalorique des intermétalliques de type Pr-Co. Le composé Pr5Co19 présente un effet magnétocalorique géant de l’ordre de 5.2 J/kg.K pour un faible champ appliqué.Les nanomatériaux intermétalliques de type Pr5Co19 peuvent être ainsi considérés comme des composés multifonctionnels. Grâce à leurs propriétés structurales, magnétiques et magnétocaloriques, ils s’avèrent être de bons candidats dans le domaine des aimants permanents, mais aussi pour la réfrigération magnétique à haute température et pour le stockage de l’hydrogène, vu le besoin croissant en énergie alternative moins polluante / Multifunctional nanomaterials based on rare-earth (R) and transition metal (T) present a major interest in scientific research. We are interrested in the Pr5Co19 alloy. This system crystallizes in the rhombohedral Ce5Co19-type structure with space group R-3m. The Curie temperature Tc is about 690 K. We determined the value of the magnetization at saturation MS = 83 Am2 / kg using the approach law to saturation. A uniaxial anisotropy with a coercive field equal to 1.5 T at room temperature were obtained.Moreover, we have observed that the insertion of a light element such as carbon or hydrogen, allows to increase the Curie temperature of the system. The Pr5Co19Hx hydrides present a reversible cycle of absorption/desorption, with a hydrogen absorption capacity equal to 12H / f.u, or 0.5H / M in total.We are also interested in the study of the magnetocaloric effect of the intermetallics Pr-Co type. We have shown that Pr5Co19 compound has a giant magnetocaloric effect, of about 5.2 J / kg.K at low field.The intermetallic nanomaterials Pr5Co19 could be used as a multifunctional compound. These results indicate that it is an attractive alloy due to its structural, magnetic and magnetocaloric properties. It could be good candidates for permanent magnets, but also for magnetic refrigeration at high temperature and for hydrogen storage

Magnétique

Intermétalliques

Réfrigération magnétique

Nanomatériaux

Stockage d'hydrogène

Structure

Magnetic

Hydrogen storage

Magnetic refrigeration

Intermetallic

Nanomaterials

Structure

Utilizing Platforms for the Observation of Chemical Transformations to Surface-Bound Noble Metal Nanoparticles in Environmentally Relevant Conditions

Glover, Richard

11 July 2013

Nanoparticles are increasingly incorporated into consumer products because of their unique, size-dependent properties. Although these properties are commercially appealing, data are lacking regarding the fate and reactivity of nanoparticles once incorporated into materials. This information gap prevents accurate assessment of hazards that these materials potentially present to consumers and the environment. To address this concern, new research is needed to investigate the reactivity and transformations of nanoparticles. This dissertation describes the use of an electron transparent characterization platform to observe nanoparticle transformations. Nanoparticles were tethered to the surface of an analysis platform, exposed to a variety of conditions, and evaluated for reactivity and response. The characterization of silver nanoparticles revealed the generation of new daughter nanoparticles on surfaces in ambient humid conditions. Our observations showed that the transport of material is highly dependent on relative humidity and that pH equilibria drives the deposition of new particles and degradation. We discovered, by applying these findings to macro-silver objects, that bulk silver generates new nanoparticles on surfaces. This illuminated the possibility of other, yet undiscovered, naturally occurring nanoparticles. In the second model system, 1.5 nm gold nanoparticles were tethered by a robust metal oxide bond from the terminal group of the stabilizing ligand. This strategy facilitated precise control over thiol ligand removal using a dilute ozone oxidation. Tracking particle oxidation over time allowed us to gain unprecedented control over core exposure, size maintenance, and surface tethering. This platform was also utilized as a proof-of-concept for direct observation of transformations in complex media. Ligand and core transformations were monitored in a variety of biologically relevant conditions using tethered nanoparticles. Morphological and chemical transformations were characterized and correlated to results from solution monitoring. The use of a platform based approach to evaluating the reactivity of nanoparticles in the environment holds promise for evaluations of nanoparticles and their transformation products. The demonstration of monitoring reactivity in systems equilibria, carefully controlled transformations, or complex media shows the versatility of this strategy. Only through the use of this analysis platform was the direct observation of nanoparticle transformations possible. This dissertation includes previously published, unpublished, and co-authored materials. / 10000-01-01

Direct observation of transformations

Environmental chemistry

Gold nanoparticles

Nanomaterials characterization

Silver nanoparticles

Synthesis and battery application of nanomaterials and the mechanism of O2 reduction in aprotic Li-O2 batteries

Liu, Zheng

January 2016

Hunting for improved energy storage devices based on rechargeable Li-ion batteries and other advanced rechargeable batteries is one of the hottest topics in today's society. Both Li- ion batteries and Li-O2 batteries have been studied within the thesis. The research work of this thesis contains two different parts. Part 1. The controlled synthesis of the extreme small sized nanoparticles and their application for Li-ion batteries; Part 2. The study of the O2 reduction mechanism in Li-O2 batteries with aprotic electrolytes. In the first part, two different types of extremely small-sized TiO2 nanoparticles with at lease on dimension less than 3 nm was synthesised via solvothermal/hydrothermal reaction, i.e., anatase nanosheets and TiO2(B). These nanoparticles were obtained without any contamination of long chain organic surfactants. A series of systematic characterisation methods were employed to analyse the size, phase purity, and surface condition. These extremely small-sized nanoparticles exhibit improved capacity, rate performance as anode materials for Li-ion batteries. The shapes of load curves of charge and discharge are significantly modified due to the reduced size of TiO2 nanoparticles. In chapter 3, we will see the variation of the capacity and the load curve shape of the anatase nanosheets according to their thickness and surface conditions. The origin of the excessive capacity is analysed based on the electrochemical data. It has been identified that both pseudocapacitive (interfacial) Li+ storage and the excessive Li+ -storage from the bulk contribute to the increased capacity. In chapter 4, the shape and size of the sub-3 nm TiO2(B) nanoparticles are studied, a method based the PXRD data is established. These nanoparticles demonstrate a reversible capacity of 221 mAh/g at a rate of 600 mA/g and remain 135 mAh/g at 18000 mA/g without significant capacity fading during cycling. In the last part, a systematic study of O2 reduction mechanism for aprotic Li-O2 batteries based on the combination of a series of electrochemical and spectroscopic data is presented. The novel mechanism unifies two previous models for the growth of Li2O2 during discharge, i.e., Li2O2 particle formation in the solution phase and Li2O2 film formation on the electrode surface. The new mechanism provides fundamental conceptions for the improvement of Li2O2 batteries and shed light on the future research of Li2O2 batteries.

Formation and optical properties of mixed multi-layered heterostructures based on all two-dimensional materials

Sheng, Yuewen

January 2017

The production of large area, high quality two-dimensional (2D) materials using chemical vapour deposition (CVD) has been an important and difficult topic in contemporary materials science research, after the discovery of the diverse and extraordinary properties exhibited by these materials. This thesis mainly focuses on the CVD synthesis of two 2D materials; bilayer graphene and monolayer tungsten disulphide (WS2). Various factors influencing the growth of each material were studied in order to understand how they affect the quality, uniformity, and size of the 2D films produced. Following this, these materials were combined to fabricate 2D vertical heterostructures, which were then spectroscopically examined and characterised. By conducting ambient pressure CVD growth with a flat support, it was found that high uniform bilayer graphene could be grown on the centimetre scale. The flat support provides for the consistent delivery of precursor to the copper catalyst for graphene growth. These results provide important insights not only into the upscaling of CVD methods for growing large area, high quality graphene and but also in how to transfer the product onto flexible substrates for potential applications as a transparent conducting electrode. Monolayer WS2 is of interest for use in optoelectronic devices due to its direct bandgap and high photoluminescence (PL) intensity. This thesis shows how the controlled addition of hydrogen into the CVD growth of WS2 can lead to separately distributed domains or centimetre scale continuous monolayer films at ambient pressure without the need for seed molecules, specially prepared substrates or low pressure vacuum systems. This CVD reaction is simple and efficient, ideal for mass-production of large area monolayer WS2. Subsequent studies showed that hexagonal domains of monolayer WS2 can have discrete segmentation in their PL emission intensity, forming symmetric patterns with alternating bright and dark regions. Analysis of the PL spectra shows differences in the exciton to trion ratio, indicating variations in the exciton recombination dynamics. These results provide important insights into the spatially varying properties of these CVD-grown TMDs materials, which may be important for their effective implementation in fast photo sensors and optical switches. Finally, by introducing a novel non-aqueous transfer method, it was possible to create vertical stacks of mixed 2D layers containing a strained monolayer of WS2, boron nitride, and graphene. Stronger interactions between WS2 on graphene was found when swapping water for IPA, likely resulting from reduced contamination between the layers associated with aqueous impurities. This transfer method is suitable for layer by layer control of 2D material vertical stacks and is shown to be possible for all CVD grown samples, a result which opens up pathways for the rapid large scale fabrication of vertical heterostructure systems with large area coverage and controllable thickness on the atomic level.

Properties, functionality and potential applications of novel modified iron nanoparticles for the treatment of 2,4,6-trichlorophenol

Underwood, Laura Ann

January 2018

2,4,6-trichlorophenol (TCP) is a pervasive carcinogenic water contaminant found in a wide variety of water and waste systems and is a pertinent model compound of broader aromatic organics, specifically organo-halide pesticides. These compounds are persistent in the environment and show resilience to regular water and waste treatment protocols thus warranting the development and implementation of novel treatment materials for improved contaminant removal. Zero-valent iron (ZVI) has demonstrated the ability to remove or degrade a wide variety of inorganic and organic water contaminants, including chlorophenols, and has been widely applied for in-situ groundwater remediation where contamination is often localised in a low-oxygen environment. ZVI's broader applications in water treatment have remained mainly limited due to corrosion, particle dispersion, and confinement issues in deployment. This work, therefore, explored the development, functionality, and potential application of new modified nZVI materials (nZVI-Osorb) and assessed their potential to improve iron's intrinsic functionality while also gauging the material's viability for TCP remediation in water and waste systems. Materials produced in this thesis were prepared utilising three different embedment procedures (1-pot, multiple additions, oxygen-free). All embedment methods resulted in tightly bound composites featuring high surface areas (340.2-449.1 sq. m/g) with net iron composition ranging from 10% to 29.78% by mass. Electron imaging microscopy verified even dispersion of iron throughout the substrate. Composite materials did not exhibit a delayed rate of atmospheric corrosion over nZVI controls evincing an 18% nZVI0 loss per day until reaching a stabilised concentration (7%) after 48 hrs. nZVI-Osorb composites did produce more favourable iron oxide species which remain conducive to electron transfer from core Fe0 atom. After 50 days, a majority of nZVI in nZVI-Osorb had oxidised to maghemite (30%) and magnetite (26%) compared to control nZVI producing 19% and 12% respectively. Unreactive hematite accounted for 47% of the control and just 36% of the composite. While 1-pot embedment allowed the most substantial control over final iron composition, the oxygen-free method allowed the most reliable preservation of initial nZVI0 concentrations through restricted oxidation. Materials generated through oxygen-free embedment were utilised in the following water treatment trials with TCP. Parameters related to sorption and degradation mechanisms of TCP by nZVI-Osorb were tested in aerobic conditions, e.g. surface and potable water. nZVI-Osorb materials demonstrated high extraction capacity for TCP from aqueous solutions (Qe=1286.4 ± 13.5 mg TCP/g Osorb, Qe=1253 ± 106.7 mg TCP/g nZVI-Osorb, pH 5.1, 120mg/L TCP) and followed pseudo second order kinetics. In the broader class of chlorophenols, sorptive affinity mirrored partitioning values with highly substituted chlorophenols displaying the highest sorption capacities. Degradation of TCP by nZVI-Osorb or nZVI controls was not observed due to corrosive hindrance and inadequate reductive capacity, suggesting that materials may not be suitable for highly aerated surface and potable water treatment systems. Environmental conditions pertinent to sorption and degradation mechanisms were evaluated to improve understanding and robustness of functionality in low-oxygen applications, such as wastewater and anaerobic digesters, where nZVI-Osorb treatment is anticipated to be advantageous to TCP sorption and methane production. pH was found to influence sorption dramatically. Acidic solutions below 5 found sorption > 90%. This capacity was reduced to < 30% when pH was raised above TCP pKa value (6.23) to 7 and above. Further trials found a positive effect on TCP sorption (+7.55%) linked to net pH reduction (5.1 to 3.3) with the addition of secondary acids (volatile fatty acids: acetic, propionic, butyric, 3x 100mg/L) commonly found in anaerobic digester systems. Salinity did not affect TCP sorption. The removal of dissolved and atmospheric oxygen increased total sorption (40ppm-+1.94%, 100ppm- +7.93%, 200ppm- +0.89%, 400mg/L- +14.59%) through reduced iron corrosion and the production of favorable iron oxides, but did not facilitate contaminant degradation. Biodegradation mechanisms for TCP have broadly been established, and new research has supported the improved cometabolic degradation of recalcitrant contaminants like TCP and PCP in nZVI-dosed anaerobic digesters. Model anaerobic digester systems (3.9 g/L nZVI-Osorb, 25mg/L TCP, 240 mg/L acetic, 120mg/L propionic, 120mg/L butyric acid) containing bioreactor sludge (62.5%) were observed through standard water quality diagnostics (pH, ORP, COD, head pressure) for 14 days and suggested that nZVI-Osorb did not inhibit cellular processes. Increased electron activity from iron corrosion and hydrogen gas production, increased overall pH and decreased total ORP in these AD systems. TCP degradation by-products (DCP, CP) were detected in dilute concentrations (< 0.01 mg/L) with poor recovery by LC-MS/MS. Results suggest that nZVIOsorb may be well-suited additive for AD systems. This study contributes to knowledge of the properties, functionality, and treatment mechanisms of metal-sorbent composites with a model chlorinated aromatic water contaminant in aerobic and anaerobic environments. The work identifies favourable environmental and process conditions to apply these materials in larger scale applications, particularly, anaerobic digestion and provides support for the continued refinement and improvement of nZVI based remediation systems.

Estudos preliminares sobre a produção de nanocelulose a partir de algodão "Never Dried" utilizando hidrólise enzimática seguida de sonicação com ultrassom / Preliminary studies on the production of nanocelulose from cotton "Never Dried", using enzymatic hydrolysis followed of sonication with ultrassom

Camargo, Marcelo de

18 January 2019

Orientador: Edison Bittencourt / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Química / Made available in DSpace on 2019-01-18T11:50:46Z (GMT). No. of bitstreams: 1 Camargo_Marcelode_M.pdf: 25344897 bytes, checksum: 8146c1fb634f94d4bb4152d5bcc07e66 (MD5) Previous issue date: 2010 / Resumo: Este estudo trata-se de um novo método de obtenção de fibras de nanocelulose a partir de algodão "Never Dried Cotton" NDC, (algodão nunca seco). O algodão classificado como NDC, apesar de possuir a mesma cristalinidade do algodão normal e muito mais poroso e, portanto, muito mais suscetível a eventuais tratamentos químicos. Esta maior porosidade deve-se ao fato de que o NDC, no seu estado natural, ainda não passou pelo processo de colapso do lumen devido a evaporação da seiva presente no seu interior. Com este colapso da estrutura, as inúmeras pontes de hidrogênio formadas entre as hidroxilas da celulose estabelecem-se em um arranjo molecular diferente do NDC, e neste novo arranjo os poros fecham-se irreversivelmente, num processo que na área de celulose chama-se "hornification", que diminui a acessibilidade da celulose. Neste trabalho aplicamos uma hidrolise enzimática seguida da sonicação com ultrasom de 400 e 1000 W de potencia, submetendo as amostras a 20, 30, 40, e 50 minutos de tratamento com ultrasom. As analises de microscopia eletrônica revelaram fibras com comprimento médio de aproximadamente 30 Fm e de ate 232 nm de diâmetro para a sonicação com ultrassom de 1000 W durante 50 minutos no algodão Never Dried. Na viscose com a mesma potencia e tempo de tratamento foram obtidas nano fibras de ate 197 nm. Para o ultrassom de 400 W obtivemos fibras com 800 nm de diâmetro apos 50 minutos de tratamento. Contudo somente com a microscopia de Transmissão eletrônica e que pudemos identificar a presença de nano fibras com ate 40 nm de diâmetro já com apenas 20 minutos de tratamento e utilizando o ultrassom de menor potencia de 400 W. As analises de medição de tamanho de partícula por laser demonstraram que as amostras obtidas com ultrassom de 1000 W são mais homogêneas em relação as suas dimensões. / Abstract: This study is about a new method of obtainning Cellulose nano fibers from cotton "Never Dried Cotton" NDC. The cotton classified as NDC, despite has the same cristalinity of the normal cotton it is much more porous and, therefore, much more susceptible to eventual chemical treatments. This higher porosity is because the NDC, in natural state, is not in process of collapse of the lumen due to evaporation of the sap in the interior of fiber. With the collapse of the structure makes the innumerable hydrogen links formed between cellulose hydroxyls to agroup themselves molecular arrangement different from NDC, and in this new arrangement the pores close on a irreversible way, in a process that in the cellulose field is called of "hornification", wich reduces the accessibility of the cellulose. In this work we apply an enzymatic hydrolysis followed the sonication with 400 and 1000 W power ultrasound, submitting the samples the 20, 30, 40, and 50 minutes of treatment with ultrasound. The analyses of electronic microscopy disclosed fibers with average length of approximately 30 Pm and up to 232 nm of diameter for the sonication with 1000 W ultrasound during 50 minutes in the Never Dried Cotton. Nano fibers of up to 197 nm were obtained from viscose, with the same power and time of treatment. Utilizing ultrasound of 400 W fibers with 800 nm of diameters were obtained after 50 minutes of treatment. However only with Transmission electronic Microscopy it was possible to identify the presence of nano fibers with up to 50 nm of diameter with only 20 minutes of treatment and using an ultrasound of 400 W power. The analyses of measurement of particle size with laser had disclosed that the samples gotten with ultrasound of 1000 W are more homogeneous compared to its dimensions. / Mestrado / Ciencia e Tecnologia de Materiais / Mestre em Engenharia Química

Algodão

Ultrassom

Hidrólise enzimática

Celulose

Nanomateriais

Cotton

Ultrasound

Hydrolysis enzimatic

Cellulose

Nanomaterials

Nouveaux matériaux riches en Mg pour le stockage d’hydrogène : composés Mg6Pd1-xMTx (MT = Ni, Ag, Cu) massifs et nanoconfinés et nanocomposites MgH2-TiH2 / Novel Mg-rich materials for hydrogen storage : bulk and nanoconfined Mg6Pd1-xTMx (TM = Ni, Ag, Cu) compounds and MgH2-TiH2 nanocomposites

Ponthieu, Marine

29 November 2013

Cette thèse est consacrée à l'étude de composés riches en magnésium innovants destinés au stockage solide de l'hydrogène. Le but est de déstabiliser l'hydrure de Mg et d'accélérer sa cinétique de sorption par des effets d'alliage et de nano-structuration. La première famille de composés concerne les phases pseudo-binaires Mg6Pd1-xMTx (MT = Ni, Ag, Cu). Leurs propriétés structurales et les effets de substitution du Pd ont été étudiés par diffraction des rayons X, microscopie électronique à balayage et microsonde de Castaing. Les propriétés thermodynamiques et cinétiques d'hydrogénation de ces matériaux ont ensuite été déterminées par réaction solide-gaz. Différents mécanismes d'hydrogénation sont mis en jeu en fonction de l'élément de substitution. La nature des phases formées lors de la réaction d'hydrogénation modifie la stabilité des systèmes métal-hydrogène. Ainsi, la transformation de métal à hydrure est caractérisée par au moins deux plateaux de pression. Le premier plateau a lieu à une pression proche de celle de Mg/MgH2, alors que le second se produit à pression plus élevée. La détermination des valeurs d'enthalpie et d'entropie de réaction ont permis de quantifier la déstabilisation atteinte. Les meilleures cinétiques de désorption sont obtenues pour l'alliage au Ni, grâce à l'effet catalytique de la phase Mg2NiH4 formée lors de l'hydrogénation. La seconde approche vise à combiner les effets d'alliage et de nano-structuration. Des nanoparticules de Mg6Pd atteignant des tailles aussi petites que 3 nm sont confinées dans des matrices carbonées nano-poreuses. En comparant leurs propriétés d'hydrogénation à celles de l'alliage massif équivalent, on démontre non seulement que la cinétique de (dés)hydrogénation des nanoparticules est bien plus rapide, mais aussi que leur état hydrogéné est déstabilisé. Enfin, des nano-composites MgH2-TiH2 ont été synthétisés par broyage mécanique sous atmosphère réactive. L'ajout d'un catalyseur (TiH2) et la nano-structuration du Mg permettent de considérablement accélérer les cinétiques d'absorption et désorption d'hydrogène dans le Mg. Afin de comprendre le rôle de la phase TiH2 sur les propriétés cinétiques remarquables de ces nano-composites, leurs propriétés structurales ont été déterminées par diffraction des rayons X et des neutrons. L'existence d'une interface cohérente entre les phases Mg et TiH2 est d'importance majeure pour faciliter la mobilité de H au sein du nano-composite. De plus, il est démontré que les inclusions de TiH2 freinent la croissance de grain de Mg/MgH2, permettant ainsi de maintenir la nano-structuration des composés lors de leur cyclage / This thesis is dedicated to the study of novel magnesium-rich compounds for solid state hydrogen storage. The aim is to destabilize Mg hydride and accelerate its sorption kinetics by alloying and nanostructuration. The first family of compounds concerns the Mg6Pd1-xTMx (TM = Ni, Ag, Cu) pseudo-binary phases. Their structural properties and the effects of Pd substitution have been studied by X-ray diffraction, scanning electron microscopy and electron microprobe analyses. Their thermodynamics and kinetics of hydrogenation have been determined by solid-gas reaction. Different hydrogenation mechanisms take place depending on the substituting element. The stability of the metal-hydrogen system is altered by the nature of the phases formed during hydrogenation reaction. Thus, metal to hydride transformation is characterized by at least two absorption plateau pressures. The pressure of the first plateau is similar to that of Mg/MgH2 while the second one occurs at higher pressure. The enthalpy and entropy of reaction are determined to quantify the destabilizing effect of Pd by TM substitution. Best desorption kinetics are found for the Ni containing alloy thanks to the catalytic effect of the Mg2NiH4 phase formed on hydrogenation. The second approach aims to combine alloying with nanostructuration effects. Nanoparticles of Mg6Pd as small as 3 nm are confined into nanoporous carbon matrix. By comparing their hydrogenation properties with those of the bulk alloy, we demonstrate that not only the (de)hydrogenation kinetics are much faster for the nanoparticles, but also that their hydrided state is destabilized. Finally, MgH2-TiH2 nanocomposites were synthesized by mechanical milling under reactive atmosphere. The addition of a catalyst (TiH2) and Mg nanostructuration allow strongly accelerating the sorption kinetics of hydrogen in Mg. To understand the role of the TiH2 phase on the outstanding kinetics of these nanocomposites, their structural properties have been determined by X-ray and neutron diffraction. The existence of a coherent interface between Mg and TiH2 phases is of major importance to facilitate H-mobility within the nanocomposite. Furthermore, it is shown that the TiH2 inclusions inhibit the Mg/MgH2 grain growth, thus maintaining the composites nanostructure during their cycling

Hydrures métalliques

Stockage d'hydrogène

Magnésium

Alliages intermétalliques

Nanomatériaux

Metal hydrides

Hydrogen storage

Magnesium

Intermetallic alloys

Nanomaterials

Biossensores EnzimÃticos para DetecÃÃo e QuantificaÃÃo de Carbamatos em Amostras de Alimentos. / Enzymatic Biosensors for the Detection and Quantification of Carbamates in Food Samples

Thiago Mielle Brito Ferreira Oliveira

10 December 2013

CoordenaÃÃo de AperfeiÃoamento de Pessoal de NÃvel Superior / Este trabalho contempla trÃs estratÃgias para o biossensoriamento de pesticidas da classe dos carbamatos (CBM) em alimentos naturais, utilizando biossensores à base de polifenoloxidases como dispositivos analÃticos: (i) eletrodo de pasta de nanotubos de carbono (EPNC) modificado com lacase de Tramites versicolor (LAC) por entrapment da enzima diretamente no material compÃsito, definido como LAC-EPNC; (ii) eletrodo de pasta de grafeno (EPG) modificado com filmes de Azul da PrÃssia (AP), seguido da imobilizaÃÃo de LAC por drop coating, definido como LAC/AP/EPG; e (iii) EPG modificado por eletrodeposiÃÃo de filme hÃbrido composto por quitosana (CS), nanopartÃculas de ouro (NpAu) e mistura das enzimas LAC e tirosinase de Agaricus bisporus (TIR), definido como LAC-TIR-NpAu-CS/EPG. Tomado por base o processo redox do substrato 4-aminofenol (4-AMF), a presenÃa dos nanotubos de carbono e do grafeno proporcionou uma sÃrie de vantagens aos dispositivos, a saber: aumento nos valores de corrente de pico, catÃlise do processo redox, melhoria na reversibilidade e, consequentemente, na cinÃtica de transferÃncia eletrÃnica. Filmes de AP (imobilizaÃÃo direta da enzima sem a necessidade de regente para cross-linking), CS (biocompatibilidade adequada, maior imobilizaÃÃo e fixaÃÃo das enzimas) e NpAu (reduÃÃo da resistÃncia a transferÃncia de carga) tambÃm apresentaram importante papel na configuraÃÃo eletrÃdica dos biossensores. As curvas analÃticas foram construÃdas por voltametria de onda quadrada, baseando-se na capacidade dos CBM (carbofurano, carbaril, formetanato, pirimicarbe, propoxur e ziram) de inibir a atividade das polifenoloxidases. Em geral, os procedimentos propostos apresentaram sensibilidade (limites de detecÃÃo variando de 0,001 a 0,093 mg kg-1) que contempla os limites mÃximos estabelecidos pelas agÃncias de seguranÃa e controle alimentar brasileira e europeia para resÃduos de CBM em hortaliÃas (tomate, alface e batata) e frutas cÃtricas (laranja, tangerina e limÃo), com baixo nÃvel de interferentes. Os ensaios de recuperaÃÃo foram realizados em extratos QuEChERS das amostras, com porcentagens de recuperaÃÃo variando de 91,0  0,1% a 101,10  0,1%; para contaminaÃÃes de 0,01 a 3,14 mg kg-1. Portanto, LAC-EPNC, LAC/AP/EPG e LAC-TIR-NpAu-CS/EPG podem ser ferramentas promissoras na anÃlise de CBM em matrizes alimentares. / This work contemplates three strategies for carbamate pesticides (CBM) biosensing in natural food, using polyphenoloxidases based biosensors as analytical device: (i) carbon nanotubes paste electrode (CNPE) modified with laccase from Tramites versicolor (LACC), namely as LACC-CNPE; (ii) graphene paste electrode (GPE) modified with Prussian Blue films (PB), followed by the LACC immobilization by drop coating, namely as LACC/PB/GPE; and (iii) GPE modified by the electrodeposition of a hybrid film composed for chitosan (CS), gold nanoparticles (AuNp) and a mixing of LACC and tyrosinase from Agaricus bisposrus (TYR), namely as LACC-TYR-AuNp-CS/GPE. Based on 4-aminophenol (4-AMP) redox process, the presence of carbon nanotubes and graphene allowed several advantages to the devices, such as: increase of the peak currents values, catalysis of the redox process, improvement of the reversibility and electronic-transfer kinetic. PB films (direct enzymatic immobilization without cross-linking reagent), CS (suitable biocompatibility, higher immobilization and fixation of the enzymes) and AuNp (reduction of the charge-transfer resistance) also showed important role on biosensors electrodic configuration. Analytical curves were constructed by square-wave voltammetry, based on CBM (carbofuran, carbaryl, formetanate, pirimicarb, propoxur and ziram) capability to inhibit the polyphenoloxidase activity. In general, the proposed procedures had sensitivity (detection limits ranging from 0.001 to 0.093 mg kg-1) in compliance with the maximum limit established by Brazilian and European food surveillance and control agencies for the analysis of CBM residues in vegetable crops (tomato, lettuce and potato) and citrus fruits (orange, tangerine and lemon), with negligent interfering effect. Recuperation experiments were carried out with QuEChERS extracts of the samples, allowing recuperation values from 91.0  0.1% to 101.1  0.1%; for spiking levels from 0.01 to 3.14 mg kg-1. Thus, LACC-CNPE, LACC/PB/GPE and LACC-TYR-AuNp-CS/GPE are promisor tools for CBM analysis in food matrices.

carbamatos

polifenoloxidases

nanomateriais

filmes condutores

biossensores enzimÃticos

carbamates

poliphenoloxidases

nanomaterials

conductor films

enzymatic biosensors

ELETROANALITICA

Preparação e estudo de nanotubos luminescentes de hidróxidos duplos lamelares (LDH) contendo íons terras raras / Preparation and study of layered double hydroxide (LDH) nanotubes containing rare earth ions

Morais, Alysson Ferreira

15 June 2018

Hidróxidos duplos lamelares (LDHs) são uma classe materiais lamelares com fórmula química [M_(1-x)^II M_x^III (OH)_2 ] [A^(n-)]_(x/n).yH_2 O (onde M^II e M^III são metais di e trivalentes, respectivamente) formados pelo empilhamento de camadas positivamente carregadas de hidróxidos metálicos intercaladas por espécies aniônicas A^(n-). Este trabalho descreve uma estratégia inédita para a produção de nanotubos de LDHs autossuportados (Ø 20 nm e comprimentos >= 100 nm) através da coprecipitação de Zn^(2+), Al^(3+) e Eu^(3+) em pH controlado e sua auto-organização sobre micelas cilíndricas do surfactante Plurônico® P-123. A subsequente extração destes agentes estruturantes através de lavagem com metanol resulta em uma rede de nanotubos cilíndricos, ocos e interconectados, formados pela deposição de multicamadas de hidróxidos duplos intercalados pela molécula sensibilizadora ácido benzeno-1,3,5-tricarboxílico (ácido trimésico, BTC). A combinação de Eu3+ nas camadas de hidróxidos e BTC no meio interlamelar resulta em nanotubos com propriedades luminescentes, demonstrando de maneira notável como modificações químicas e morfológicas nos LDHs podem levar ao remodelamento das suas propriedades físico-químicas e consequentemente direcionar suas aplicações de maneira desejável. / Layered double hydroxides are a class of lamellar compounds with chemical formula [M_(1-x)^II M_x^III (OH)_2 ] [A^(n-)]_(x/n).yH_2 O (with M^II and M^III being di and trivalent metals, respectively) that are formed by the stacking of positively charged mixed-valence metal hydroxide sheets intercalated by anionic species A^(n-). This work describes a new strategy for the synthesis of self-supporting mesoporous LDH nanotubes (Ø 20 nm and length >= 100 nm) by coprecipitation of Zn^(2+), Al^(3+) and Eu^(3+) around non-ionic worm-like micelles of Pluronic® P-123 in controlled pH. Subsequent extraction of the structure-directing agent with methanol results in a network of interconnected, well-defined, multi-walled and hollow cylindrical LDH nanotubes intercalated by the sensitizing ligand BTC (1,3,5-benzenetricarboxilate). The combination of Eu^(3+) in the hydroxide layers and BTC in the interlayers results in nanotubes with luminescence properties in a notable demonstration on how chemical and morphological changes in LDHs can lead to materials with tuned physico chemical properties that can be tailored towards a range of applications.

hidróxidos duplos lamelares

layered double hydroxides

luminescence

luminescência

materiais porosos

nanomateriais

nanomaterials

nanotubes

nanotubos

porous materials