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Biosynthesis and characterization of metallic nanoparticles produced by paenibacillus castaneaeHiebner, Dishon Wayne January 2017 (has links)
A dissertation submitted to the Faculty of Science of the University of
Witwatersrand, Johannesburg, in full fulfilment of the requirements for the degree
of Master of Science.
May 2017 / Nanomaterials (NMs) have been shown to exhibit unique physical and chemical
properties that are highly size and shape-dependent. The ability to control synthesis
of nanoparticles (NPs) with particular shapes and sizes can lead to exciting new
applications or enhancements of current systems in the fields of optics, electronics,
catalytics, biomedicine and biotechnology. Due to increased chemical pollution as
well as health concerns, biological synthesis of NMs has quickly emerged as
potentially being an eco-friendly, scalable, and clean alternative to chemical and
physical synthesis. In this study, the inference that the heavy metal-resistant
bacteria, Paenibacillus castaneae, has the propensity to synthesize metal NPs was
validated.
NP formation was achieved after the exposure of bacterial cell biomass or cell-free
extracts (CFE) to excess metal ion precursors in solution. These include lead nitrate
and calcium sulphate dehydrate, gold (III) chloride trihydrate and silver nitrate,
respectively. All reactions were incubated at 37 °C for 72 h at 200 rpm and observed
for a colour change. UV–visible (UV-Vis) spectral scans (200 nm – 900 nm) were
measured on a Jasco V-630 UV-Vis spectrophotometer. For scanning electron
microscopy (SEM), samples were fixed, dehydrated and loaded onto carbon-coated
aluminium stubs. The stubs were then sputter-coated with either Au/Pd or Cr and
analysed on the FEI Nova Nanolab 600 FEG-SEM/FIB. Size distribution analysis
was done using transmission electron microscopy (TEM) using the FEI Tecnai T12
TEM and Image J software. Powder X-ray diffraction measurements were carried
out on a Rigaku Miniflex-II X-ray diffractrometer.
Colour changes indicative of the synthesis of PbS, Au and Ag NPs were observed
as a white precipitate (PbS), purple (Au) and yellow-brown (Ag) colour,
respectively. This was confirmed by absorbance peaks at 325 nm and 550 nm (PbS),
595 nm (Au) and 440 nm (Ag) from UV-Vis analyses. Exposure of P. castaneae
biomass and CFE to PbS ions in solution resulted in the production of nanospheres,
irregularly-shaped NPs, nanorods, nanowires as well as large nanoflowers.
Exposure of P. castaneae biomass to Au3+ ions in solution produced Au
nanospheres, nanotriangles, nanohexagons, nanopentagons and nanopolyhedrons.
Ag/AgCl NP production occurred using both the P. castaneae biomass and CFE,
and resulted in the synthesis of nanospheres only.
This is the first report of the biosynthesis of such a diverse set of anisotropic NPs
by P. castaneae. It is also the first instance in which anisotropic PbS nanorods and
nanowires, 3-D Au nanoprisms as well as “rough” Ag/AgCl nanospheres were
bacterially produced. This study serves as an eco-friendly approach for the
synthesis of NPs that is a simple yet amenable method for the large-scale
commercial production of nanoparticles with technical relevance. This in turn
expands the limited knowledge surrounding the biological synthesis of heavy metal
NMs. / MT 2017
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Computational Studies of the Mechanical Response of Nano-Structured MaterialsBeets, Nathan James 18 May 2020 (has links)
In this dissertation, simulation techniques are used to understand the role of surfaces, interfaces, and capillary forces on the deformation response of bicontinuous metallic composites and porous materials. This research utilizes atomistic scale modeling to study nanoscale deformation phenomena with time and spatial resolution not available in experimental testing. Molecular dynamics techniques are used to understand plastic deformation of metallic bicontinuous lattices with varying solid volume fraction, connectivity, size, surface stress, loading procedures, and solid density.
Strain localization and yield response on nanoporous gold lattices as a function of their solid volume fraction are investigated in axially strained periodic samples with constant average ligament diameter. Simulation stress results revealed that yield response was significantly lower than what can be expected form the Gibson-Ashby formalism for predicting the yield response of macro scale foams. It was found that the number of fully connected ligaments contributing to the overall load bearing structure decreased as a function of solid volume fraction. Correcting for this with a scaling factor that corrects the total volume fraction to "connected, load bearing" solid fraction makes the predictions from the scaling equations more realistic.
The effects of ligament diameter in nanoporous lattices on yield and elastic response in both compressive and tensile loading states are reported. Yield response in compression and tension is found to converge for the two deformation modes with increasing ligament diameter, with the samples consistently being stronger in tension, but weaker in compression. The plastic response results are fit to a predictive model that depends on ligament size and surface parameter (f). A modification is made to the model to be in terms of surface area to volume ratio (S/V) rather than ligament diameter (1/d) and the response from capillary forces seems to be more closely modeled with the full surface stress parameter rather than surface energy.
Fracture response of a nanoporous gold structure is also studied, using the stress intensity-controlled equations for deformation from linear elastic fracture mechanics in combination with a box of atoms, whose interior is governed by the molecular dynamics formalism. Mechanisms of failure and propagation, propagation rate, and ligament-by-ligament deformation mechanisms such as dislocations and twin boundaries are studied and compared to a corresponding experimental nanoporous gold sample investigated via HRTEM microscopy. Stress state and deformation behavior of individual ligaments are compared to tensile tests of cylinder and hyperboloid nanowires with varying orientations. The information gathered here is used to successfully predict when and how ligaments ahead of the crack tip will fracture.
The effects of the addition of silver on the mechanical response of a nanoporous lattice in uniaxial tension and compression is also reported. Samples with identical morphology to the study of the effects of ligament diameter are used, with varying random placement concentrations of silver atoms. A Monte Carlo scheme is used to study the degree of surface segregation after equilibration in a mixed lattice. Dislocation behavior and deformation response for all samples in compression and tension are studied, and yield response specifically is put in the context of a surface effect model.
Finally, a novel bicontiuous fully phase separated Cu-Mo structure is investigated, and compared to a morphologically similar experimental sample. Composite interfacial energy and interface orientation structure are studied and compared to corresponding experimental results. The effect of ligament diameter on mechanical response in compressive stress is investigated for a singular morphology, stress distribution by phase is investigated in the context of elastic moduli calculated from the full elastic tensor and pure elemental deformation tests. Dislocation evolution and its effects on strain hardening are put in the context of elastic strain, and plastic response is investigated in the context of a confined layer slip model for emission of a glide loop. The structure is shown to be an excellent, low interface energy model that can arrest slip plane formation while maintaining strength close to the theoretical prediction.
Dislocation content in all samples was quantified via the dislocation extraction algorithm. All visualization, phase dependent stress analysis, and structural/property analysis was conducted with the OVITO software package, and its included python editor. All simulations were conducted using the LAMMPS molecular dynamics simulation package.
Overall, this dissertation presents insights into plastic deformation phenomena for nano-scale bicontinuous metallic lattices using a combination of experimentation and simulation. A more holistic understanding of the mechanical response of these materials is obtained and an addition to the theory concerning their mechanical response is presented. / Doctor of Philosophy / Crystalline metals can be synthesized to have a sponge-like structure of interconnected ligaments and pores which can drastically change the way that the material chemically interacts with its environment, such as how readily it can absorb oxygen and hydrogen ions. This makes it attractive as a catalyst material for speeding up or altering chemical reactions. The change in structure can also drastically change how the material responds when deformed by pressing, pulling, tearing or shearing, which are important phenomena to understand when engineering new technology. High surface or interface area to volume ratios can cause a massive surface-governed capillary force (the same force that causes droplets of water to bead up on rain coat) and lead to a higher pressure within the material. The effect that both structure and capillary forces have on the way these materials react when deformed has not been established in the context of capillary force theory or crystalline material plasticity theory. For this reason, we investigate these materials using simulation methods at the atomic level, which can give accurate and detailed data on the stress and forces felt atom-by-atom in a material, as well as defects in the material, such as dislocations and vacancies, which are the primary mechanisms that cause the crystal lattice to permanently deform and ultimately break. A series of parameters are varied for multiple model systems to understand the effects of various scenarios, and the understanding provided by these tests is presented.
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Superparamagnetic iron-oxide based nanoparticles for the separation and recovery of precious metals from solutionLakay, Eugene Marlin 03 1900 (has links)
Thesis (MSc (Chemistry and Polymer Science))--University of Stellenbosch, 2009. / Please refer to full text to view abstract
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Nanostructuration of epoxy networks by using polyhedral oligomeric silsesquioxanes POSS and its copolymersChen, Jiang Feng 08 June 2012 (has links) (PDF)
A series of hybrid component based on reactive polyhedral oligomeric silsesquioxane(POSS) precusors and its reactive copolymers of PGMA were synthesized and utilized to nanobuild in epoxy. Reactive POSS and copolymer dispersed in homogenous in matrix, overcomed POSS-POSS interaction, which resulted in macroscale phase separation. The nanocomposites obtained were analyzed by Scanning electron microscopy, Transmission electron microscopy, X-ray scattering and dynamic mechanical. An analogue of POSS (denoted as POSSMOCA) was synthesized via addition reaction, which had reactive amino group bonding into epoxy network and improved the thermostability, because of the structural silicon, nitrogen and halogen. Epoxy/polyhedral oligomeric silsesquioxanes (POSS) hybrid composites were prepared from prereaction between trifunctional silanol POSS-OH and diglycidyl ether of bisphenol A (DGEBA) via silanol and the oxirane group. Reactive POSS-PGMA was polymerized via Reversible addition-fragmentation transfer polymerization. It was easy to tail the compatibility of the epoxide block copolymer with a step-growth polymerized matrix, to form nanostructure via reaction with PGMA segements. In the case of inert POSS-PMMA copolymers modified epoxy, topology of copolymer defined the final morphology and interaction between epoxy and them, because of directional hydrogen bonding and dilution effect. Tg of different epoxide conversion, obeyed of Gordon-Taylor equation and Kwei equation, k which reflected the interaction of modifier and DGEBA/MEDA and epoxy/amine oligomers, was consistent of the rheology and dynamic results.
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Physical, electrical and electrochemical characterizations of transition metal compounds for electrochemical energy storageYuan, Qifan 03 February 2015 (has links)
Electrochemical energy storage has been widely used in various areas, including new energy sources, auto industry, and information technology. However, the performance of current electrochemical energy storage devices does not meet the requirements of these areas that include both high energy and power density, fast recharge time, and long lifetime. One solution to meet consumer demands is to discover new materials that can substantially enhance the performance of electrochemical energy storage devices. In this dissertation we report four transition metal materials systems with potential applications in electrochemical energy storage.
Nanoscale and nanostructured materials are expected to play important roles in energy storage devices because of their enhanced and sometimes unique physical and chemical properties. Studied here is the comparative electrochemical cation insertion into a nanostructured vanadium oxide, a promising electrode material candidate, for the alkali metal ions Li+, Na+ and K+ and the organic ammonium ion, in aqueous electrolyte solutions. Observed are the distinctive insertion processes of the different ions, which yield a correlation between physical degradation of the material and a reduction of the calculated specific charge. The results reveal the potential of this nanostructured vanadium oxide material for energy storage. Vanadium based electrochemical systems are of general interest, and as models for vanadium based solid-state electrochemical processes, the solution state and the solid-state electrochemical properties of two cryolite-type compounds, (NH4)3VxGa1-xF6, and Na3VF6, are studied. The electrochemical behavior of (NH4)3VxGa1-xF6 explored the possibility of using this material as an electrolyte for solid state energy storage systems.
Zeolite-like materials have large surface to volume ratios, with ions and neutral species located in the nanometer sized pores of the 3-dimensional framework, potentially yielding high energy density storage capabilities. Yet the insulating nature of known zeolite-like materials has limited their use for electrical energy storage. Studied here are two vanadium based zeolite-like structures, the oxo-vanadium arsenate [(As6V15O51)-9]∞, and the oxo-vanadium phosphate [(P6V15O51)-9]∞, where the former shows electronic conduction in the 3-dimensional framework. Mixed electronic and ionic conductivity, from the framework and from the cations located within the framework, respectively, is measured in the oxo-vanadium arsenate, and allows the use of this material in electrochemical double-layer capacitor configuration for energy storage. By contrast, the oxo-vanadium phosphate shows ionic conduction only. Lastly, a new strontium manganese vanadate with a layered structure exhibiting mixed protonic and electronic conductivity is studied. The various transition metal compounds and materials systems experimentally studied in this thesis showcase the importance of novel materials in future energy storage schemes. / Ph. D.
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Self-Organization of Bioinspired Fibrous SurfacesKang, Sung Hoon 18 December 2012 (has links)
Nature uses fibrous surfaces for a wide range of functions such as sensing, adhesion, structural color, and self-cleaning. However, little is known about how fiber properties enable them to self-organize into diverse and complex functional forms. Using polymeric micro/nanofiber arrays with tunable properties as model systems, we demonstrate how the combination of mechanical and surface properties can be harnessed to transform an array of anchored nanofibers into a variety of complex, hierarchically organized dynamic functional surfaces. We show that the delicate balance between fiber elasticity and surface adhesion plays a critical role in determining the shape, chirality, and hierarchy of the assembled structures. We further report a strategy for controlling the long-range order of fiber assemblies by manipulating the shape and movement of the liquid-vapor interface. Our study provides fundamental understanding of the pattern formation by self-organization of bioinspired fibrous surfaces. Moreover, our new strategies offer a foundation for designing a vast assortment of functional surfaces with adhesive, optical, water-repellent, capture and release, and many more capabilities with the structural and dynamic sophistication of their biological counterparts. / Engineering and Applied Sciences
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Étude de nouveaux matériaux composites de type Si/Sn Ni/Al/C pour électrode négative de batteries lithium ion / Study of a new Si/Sn Ni/Al/C composite material used as negative electrode for lithium ion batteriesEdfouf, Zineb 09 December 2011 (has links)
Ce mémoire est consacré à l'étude de nouveaux matériaux composites de type Si/Sn-Ni/Al/C pour former des électrodes négatives de batteries lithium ion. La microstructure de ces matériaux se présente sous la forme de nanoparticules de Si enrobées dans une matrice conductrice constituée de carbone et d'un composé intermétallique Ni3,4Sn4. La nanostructure et la composition du matériau composite lui confèrent de très bonnes performances en termes de capacité réversible, de stabilité électrochimique, et de cinétique de réaction. La mécanosynthèse a été choisie comme méthode d'élaboration. Les propriétés structurales et chimiques du composite ont été déterminées par analyses DRX, par microscopies électroniques MET et MEB, par analyses EDX et EFTEM et par spectroscopie Mössbauer de 119Sn. La caractérisation électrochimique a été réalisée par cyclage galvanostatique et par voltamétrie cyclique. La réactivité de ces matériaux envers le lithium a été étudiée par analyses DRX et spectroscopie Mössbauer de 119Sn in-situ. Ce mémoire détaille les résultats structuraux et électrochimiques obtenus pour différents matériaux composites basés sur Ni3,4Sn4 en ajoutant les éléments C, Al et Si. Une étude des mécanismes réactionnels lors du broyage mécanique ainsi que pendant le cyclage électrochimique a été effectuée et le rôle des différents éléments a été mis en évidence. Enfin, une discussion sur l'influence de la microstructure sur les performances électrochimiques des matériaux composites est donnée. Les meilleures performances électrochimiques sont obtenues pour le composite de composition nominale Ni0,14Sn0,17Si0,32Al0,04C0,35. Il présente une capacité réversible de 920 mAh/g avec une très bonne stabilité sur 280 cycles. Le matériau possède une excellente cinétique de délithiation : 90% de la capacité peut être délivrée en moins de 5 minutes. La capacité irréversible (20%) reste toutefois élevée et doit être encore améliorée en stabilisant l'interface solide/électrolyte (SEI) / This study is devoted to a new Si/Sn-Ni/Al/C composite material usable as negative electrode for lithium-ion batteries. The composite microstructure is made from Si nanoparticles embedded in a matrix, consisting of conductive carbon and Ni3.4Sn4 intermetallic compound. The nanostructure and composition of the composite material give excellent properties regarding reversible capacity, electrochemical stability, and reaction kinetics. Mechanical alloying has been chosen as synthesis method. The material structural and chemical properties have been determined by XRD analysis, by electron microscopy TEM and SEM, by EDX and EFTEM analysis and 119Sn Mössbauer spectroscopy. The electrochemical characterization was carried out by galvanostatic cycling and cyclic voltammetry. Lithium reactivity of these materials was studied by in-situ XRD analysis and 119Sn Mössbauer spectroscopy. This manuscript details the structural and electrochemical results obtained from various composite materials based on Ni3.4Sn4 by adding C, Al and Si elements. Reaction mechanisms during mechanical alloying and during electrochemical cycling have been investigated and the role of the different elements has been demonstrated. Finally, a discussion of the microstructure influence on the electrochemical performance of the composite materials is given. The best electrochemical properties are obtained for the composite material with nominal composition Ni0.14Sn0.17Si0.32Al0.04C0.35, which has a reversible capacity of 920 mAh/g with a very good stability of 280 cycles. Excellent kinetics during délithiation are obtained : 90% of capacity can be delivered in less than 5 minutes. However, the irreversible capacity (20 %) remains high and should be improved by stabilizing the solid/electrolyte interface (SEI)
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Nanostructuration of epoxy networks by using polyhedral oligomeric silsesquioxanes POSS and its copolymers / Nanostructuration de réseaux époxy des à l'aide de polyédriques oligomères POSS silsesquioxanes et ses copolymèresChen, Jiangfeng 08 June 2012 (has links)
Une série de composant hybride basée sur réactives polyédriques oligomères silsesquioxane (POSS) precusors et ses copolymères réactifs de PGMA ont été synthétisés et utilisés pour nanobuild en époxy. POSS réactifs et de copolymères en dispersion dans la matrice homogène dans, au délà de POSS-POSS interaction, ce qui a entraîné la séparation de phase macroscopique. Les nanocomposites obtenus ont été analysés par microscopie électronique à balayage, microscopie électronique à transmission, diffusion des rayons X et l'analyse mécanique dynamique. Un analogue de POSS (notée POSSMOCA) a été synthétisé par réaction d'addition, qui a réactive liaison groupe amino dans le réseau époxy et d'améliorer la stabilité thermique, en raison du silicium, d'azote et un atome d'halogène structurel. Époxy / polyédriques silsesquioxanes oligomères (POSS) composites hybrides ont été préparés à partir de pré-réaction entre l'éther de silanol POSS-OH et diglycidylique trifonctionnel de bisphénol A (DGEBA) par l'intermédiaire du silanol et un groupe oxiranne. Réactif POSS-PGMA a été polymérisé par polymérisation par transfert de réversible par addition-fragmentation. Il est facile à queue de la compatibilité du copolymère séquencé époxyde avec une matrice de l'étape de croissance-polymérisé, pour former par réaction avec nanostructure segements PGMA. Dans le cas d'inertes POSS-PMMA copolymères modifiés époxy, topologie de copolymère défini la morphologie finale et l'interaction entre époxy et entre eux, en raison de la liaison hydrogène directionnelle à effet de dilution. Tg de conversion époxyde différente, obéi de Gordon-Taylor équation et l'équation Kwei, k qui reflète l'interaction de modificateur et les oligomères DGEBA / MEDA et époxy / amine, était cohérente de la rhéologie et les résultats dynamiques. / A series of hybrid component based on reactive polyhedral oligomeric silsesquioxane(POSS) precusors and its reactive copolymers of PGMA were synthesized and utilized to nanobuild in epoxy. Reactive POSS and copolymer dispersed in homogenous in matrix, overcomed POSS-POSS interaction, which resulted in macroscale phase separation. The nanocomposites obtained were analyzed by Scanning electron microscopy, Transmission electron microscopy, X-ray scattering and dynamic mechanical. An analogue of POSS (denoted as POSSMOCA) was synthesized via addition reaction, which had reactive amino group bonding into epoxy network and improved the thermostability, because of the structural silicon, nitrogen and halogen. Epoxy/polyhedral oligomeric silsesquioxanes (POSS) hybrid composites were prepared from prereaction between trifunctional silanol POSS-OH and diglycidyl ether of bisphenol A (DGEBA) via silanol and the oxirane group. Reactive POSS-PGMA was polymerized via Reversible addition-fragmentation transfer polymerization. It was easy to tail the compatibility of the epoxide block copolymer with a step-growth polymerized matrix, to form nanostructure via reaction with PGMA segements. In the case of inert POSS-PMMA copolymers modified epoxy, topology of copolymer defined the final morphology and interaction between epoxy and them, because of directional hydrogen bonding and dilution effect. Tg of different epoxide conversion, obeyed of Gordon-Taylor equation and Kwei equation, k which reflected the interaction of modifier and DGEBA/MEDA and epoxy/amine oligomers, was consistent of the rheology and dynamic results.
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