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Author: Benjamin Adam Legg Publisher: ISBN: Category : Languages : en Pages : 117
Book Description
Nucleation, growth, and aggregation are interconnected processes which control the formation nanoparticles within aqueous environments and the development of nanoparticle structures. These processes are of fundamental engineering importance for the development of new nanoparticle synthesis methodologies and the creation of hierarchical self-assembled structures. They are also fundamentally important concepts for describing how nanoparticles and minerals are formed and distributed throughout the natural environment. The development of more sophisticated models for nucleation, growth, and aggregation within the aqueous environment has become a pressing scientific need, because nanoparticle size, shape, and aggregate structure are known to impact particle reactivity, bioavailability, transport and fate within the environment. In recent years, it has become apparent that complex interactions may exist between the processes of nucleation, growth, and aggregation, and these interactions are especially important during the formation of nanometer scale particles. For example, aggregation has been shown to serve as a mechanism for the growth of nanocrystals, and as a potential driver for phase transformations. However, the details of these interactions are not fully understood. In this work, a combination of advanced in situ characterization techniques, including cryogenic transmission electron microscopy (cryo-TEM) and small angle x-ray scattering (SAXS), have been combined to better understand the development of nanoscale structures in aqueous systems. These techniques are complementary. Cryo-TEM provides new capabilities for nanoscale imaging of particles in aqua. It is especially useful for imaging fragile aggregate structures, which cannot be dried without damage, and for obtaining snapshots of reactive solutions that are evolving over time. Furthermore, cryo-TEM can be used to produce three-dimensional tomographic reconstructions (cryo-ET), providing structural models for particles and nanoparticles. However, TEM methodologies are limited by sampling statistics and are not ideal for determining the kinetics of structural change. SAXS is a complementary method that allows suspension properties such as particle size and aggregate structure to be characterized in a time-resolved fashion. SAXS has the potential to provide more statistically robust measurements, and to provide detailed reaction kinetics. However, SAXS data interpretation requires some level of a priori knowledge of the structure being characterized. Thus, by combining SAXS with cryo-TEM, a structurally accurate and statistically robust description of nanoparticle aggregate structure can be obtained. This dissertation consists of four studies, which seek explain how iron oxyhydroxide nanoparticles nucleate and develop new structures via aggregation, within the aqueous environment. The aim of the first study is to determine the structure of ferrihydrite nanoparticle aggregates in aqua. This is achieved using complimentary cryo-TEM and SAXS methodologies. Ferrihydrite nanoparticles are known to form complex aggregate structures. Interpretation of SAXS data is difficult due to suspension polydispersity. Cryo-ET is used to obtain three-dimensional images of the nanoparticle suspensions. A variety of aggregate structures are observed, with branched networks of linear chains of particles being prevalent in most suspensions. The tomographic structural models are processed to determine aggregate fractal dimensions, using an autocorrelation function based approach. These results are combined with SAXS data to obtain a more comprehensive understanding of the suspension complexity. The networks of linear chains are shown to possess low fractal dimensions, between 1.0 and 1.4; significantly lower than would be expected from traditional models for aggregation. This has important consequences for the aggregate's physical behavior, and allows very large aggregates to exist in stable colloidal suspension without flocculation. The second study addresses how the ferrihydrite aggregate structure responds to changes in the ionic strength of the suspension, and how low-dimensional aggregate structures may influence nanoparticle transport through subsurface environments. Introducing ferrihydrite particle aggregates into solutions of 2 mM to 50 mM NaNO3 is shown to induce aggregate collapse, with more salt leading to the formation of denser aggregate structures and eventual flocculation. Complementary experiments show that millimolar quantities of NaNO3 induce a fundamental change in nanoparticle transport through a saturated quartz sand column. In deionized water, where low fractal dimension aggregates are stable, nanoparticles deposit evenly throughout the column, which soon saturates with particles so that subsequent injections are transported freely. When conditions favor aggregate collapse, dense localized accumulations occur and more nanoparticles can be deposited within the column. These deposits may be mechanically unstable, leading to irregular transport behavior. In the third study, the relationship between aggregation and iron oxyhydroxide phase transformations is explored. Previous researchers have found that akaganeite ([beta]-FeOOH) nanoparticles transform to create hematite ([alpha]-Fe2O3) nano-spindles in response to hydrothermal aging, but the mechanism of transformation is unknown. Some researchers have proposed a process based on the aggregation of hematite precursors, while others advocated for dissolution and re-precipitation mechanisms. In this study, the kinetics of the phase transformation from akaganeite to hematite is studied, and cryo-TEM is used to characterize the aggregate structures in the transforming suspension. The hematite spindles are shown to be nanoporous, while akaganeite nanoparticles display a tendency for oriented aggregation. Hematite spindles are frequently found in intimate contact with akaganeite nanoparticle aggregates during the process of phase transformation, suggesting a model for phase transformation in which the dehydration of akaganeite to form hematite is enhanced by aggregation. In the final study, the nucleation and growth of akaganeite nanoparticles from acidic (pH 1.5-3) FeCl3 solutions is tracked with in situ small angle x-ray scattering (SAXS). The hydrothermal precipitation process studied can generate highly monodisperse particles, whose size, shape, and nucleation rate can be tuned by varying solution saturation and temperature. Classical nucleation modeling is applied to determine new values for the interfacial energy of ferric oxyhydroxide clusters. The interfacial energy (interfacial tension) of the nucleus is shown to be pH dependent and ranges from 0.06 to 0.12 J/m2 within the range of experimental conditions. The interfacial tension decreases with decreasing pH. At the onset of nucleation, this corresponds to very small critical nuclei, containing just 4 to 30 iron atoms. The free energy of the early critical nuclei (40-70 kJ/mol) is found to be small relative to the effective activation energy for particle growth (140-200 kJ/mol). This suggests a situation where differences in growth kinetics may be as important for determining the first formed phase as differences in precipitate solubility or interfacial energy. A thermodynamic construction for the free energy of an embryonic cluster is presented that can be extended to clusters of arbitrarily small size, including iron monomers. This construction can be used to define the interfacial tension of dissolved species, and determine this interfacial tension from readily available solubility data. The interfacial tension of the monomer is shown to closely track the experimentally determined interfacial tension of the critical nucleation clusters, suggesting a new method for estimating oxyhydroxide interfacial tensions when direct experimental measurements are unavailable. In combination, these studies reveal the wide array of structures and behaviors that can occur in aqueous suspensions of ferric oxyhydroxide nanoparticles. In aqua methodologies with nanoscale resolution have allowed novel nanoparticle structures to be observed (e.g. linear particle chains and nanoporous hematite), and have been used to show the impact of nanoparticle aggregation on a variety of important physical processes (e.g. nanoparticle transport and phase transformation). These in aqua methods are also powerful tools for quantitative characterization of fundamental processes such as nanoparticle nucleation and growth; allowing important material properties (i.e. interfacial energy) that were previously unknown to be obtained. This type of information will allow for the refinement of existing iron oxyhydroxide synthesis approaches, to provide better control over particle size, shape, and phase, and will allow scientists to predict where nanoparticles may form within the environment.
Author: Benjamin Adam Legg Publisher: ISBN: Category : Languages : en Pages : 117
Book Description
Nucleation, growth, and aggregation are interconnected processes which control the formation nanoparticles within aqueous environments and the development of nanoparticle structures. These processes are of fundamental engineering importance for the development of new nanoparticle synthesis methodologies and the creation of hierarchical self-assembled structures. They are also fundamentally important concepts for describing how nanoparticles and minerals are formed and distributed throughout the natural environment. The development of more sophisticated models for nucleation, growth, and aggregation within the aqueous environment has become a pressing scientific need, because nanoparticle size, shape, and aggregate structure are known to impact particle reactivity, bioavailability, transport and fate within the environment. In recent years, it has become apparent that complex interactions may exist between the processes of nucleation, growth, and aggregation, and these interactions are especially important during the formation of nanometer scale particles. For example, aggregation has been shown to serve as a mechanism for the growth of nanocrystals, and as a potential driver for phase transformations. However, the details of these interactions are not fully understood. In this work, a combination of advanced in situ characterization techniques, including cryogenic transmission electron microscopy (cryo-TEM) and small angle x-ray scattering (SAXS), have been combined to better understand the development of nanoscale structures in aqueous systems. These techniques are complementary. Cryo-TEM provides new capabilities for nanoscale imaging of particles in aqua. It is especially useful for imaging fragile aggregate structures, which cannot be dried without damage, and for obtaining snapshots of reactive solutions that are evolving over time. Furthermore, cryo-TEM can be used to produce three-dimensional tomographic reconstructions (cryo-ET), providing structural models for particles and nanoparticles. However, TEM methodologies are limited by sampling statistics and are not ideal for determining the kinetics of structural change. SAXS is a complementary method that allows suspension properties such as particle size and aggregate structure to be characterized in a time-resolved fashion. SAXS has the potential to provide more statistically robust measurements, and to provide detailed reaction kinetics. However, SAXS data interpretation requires some level of a priori knowledge of the structure being characterized. Thus, by combining SAXS with cryo-TEM, a structurally accurate and statistically robust description of nanoparticle aggregate structure can be obtained. This dissertation consists of four studies, which seek explain how iron oxyhydroxide nanoparticles nucleate and develop new structures via aggregation, within the aqueous environment. The aim of the first study is to determine the structure of ferrihydrite nanoparticle aggregates in aqua. This is achieved using complimentary cryo-TEM and SAXS methodologies. Ferrihydrite nanoparticles are known to form complex aggregate structures. Interpretation of SAXS data is difficult due to suspension polydispersity. Cryo-ET is used to obtain three-dimensional images of the nanoparticle suspensions. A variety of aggregate structures are observed, with branched networks of linear chains of particles being prevalent in most suspensions. The tomographic structural models are processed to determine aggregate fractal dimensions, using an autocorrelation function based approach. These results are combined with SAXS data to obtain a more comprehensive understanding of the suspension complexity. The networks of linear chains are shown to possess low fractal dimensions, between 1.0 and 1.4; significantly lower than would be expected from traditional models for aggregation. This has important consequences for the aggregate's physical behavior, and allows very large aggregates to exist in stable colloidal suspension without flocculation. The second study addresses how the ferrihydrite aggregate structure responds to changes in the ionic strength of the suspension, and how low-dimensional aggregate structures may influence nanoparticle transport through subsurface environments. Introducing ferrihydrite particle aggregates into solutions of 2 mM to 50 mM NaNO3 is shown to induce aggregate collapse, with more salt leading to the formation of denser aggregate structures and eventual flocculation. Complementary experiments show that millimolar quantities of NaNO3 induce a fundamental change in nanoparticle transport through a saturated quartz sand column. In deionized water, where low fractal dimension aggregates are stable, nanoparticles deposit evenly throughout the column, which soon saturates with particles so that subsequent injections are transported freely. When conditions favor aggregate collapse, dense localized accumulations occur and more nanoparticles can be deposited within the column. These deposits may be mechanically unstable, leading to irregular transport behavior. In the third study, the relationship between aggregation and iron oxyhydroxide phase transformations is explored. Previous researchers have found that akaganeite ([beta]-FeOOH) nanoparticles transform to create hematite ([alpha]-Fe2O3) nano-spindles in response to hydrothermal aging, but the mechanism of transformation is unknown. Some researchers have proposed a process based on the aggregation of hematite precursors, while others advocated for dissolution and re-precipitation mechanisms. In this study, the kinetics of the phase transformation from akaganeite to hematite is studied, and cryo-TEM is used to characterize the aggregate structures in the transforming suspension. The hematite spindles are shown to be nanoporous, while akaganeite nanoparticles display a tendency for oriented aggregation. Hematite spindles are frequently found in intimate contact with akaganeite nanoparticle aggregates during the process of phase transformation, suggesting a model for phase transformation in which the dehydration of akaganeite to form hematite is enhanced by aggregation. In the final study, the nucleation and growth of akaganeite nanoparticles from acidic (pH 1.5-3) FeCl3 solutions is tracked with in situ small angle x-ray scattering (SAXS). The hydrothermal precipitation process studied can generate highly monodisperse particles, whose size, shape, and nucleation rate can be tuned by varying solution saturation and temperature. Classical nucleation modeling is applied to determine new values for the interfacial energy of ferric oxyhydroxide clusters. The interfacial energy (interfacial tension) of the nucleus is shown to be pH dependent and ranges from 0.06 to 0.12 J/m2 within the range of experimental conditions. The interfacial tension decreases with decreasing pH. At the onset of nucleation, this corresponds to very small critical nuclei, containing just 4 to 30 iron atoms. The free energy of the early critical nuclei (40-70 kJ/mol) is found to be small relative to the effective activation energy for particle growth (140-200 kJ/mol). This suggests a situation where differences in growth kinetics may be as important for determining the first formed phase as differences in precipitate solubility or interfacial energy. A thermodynamic construction for the free energy of an embryonic cluster is presented that can be extended to clusters of arbitrarily small size, including iron monomers. This construction can be used to define the interfacial tension of dissolved species, and determine this interfacial tension from readily available solubility data. The interfacial tension of the monomer is shown to closely track the experimentally determined interfacial tension of the critical nucleation clusters, suggesting a new method for estimating oxyhydroxide interfacial tensions when direct experimental measurements are unavailable. In combination, these studies reveal the wide array of structures and behaviors that can occur in aqueous suspensions of ferric oxyhydroxide nanoparticles. In aqua methodologies with nanoscale resolution have allowed novel nanoparticle structures to be observed (e.g. linear particle chains and nanoporous hematite), and have been used to show the impact of nanoparticle aggregation on a variety of important physical processes (e.g. nanoparticle transport and phase transformation). These in aqua methods are also powerful tools for quantitative characterization of fundamental processes such as nanoparticle nucleation and growth; allowing important material properties (i.e. interfacial energy) that were previously unknown to be obtained. This type of information will allow for the refinement of existing iron oxyhydroxide synthesis approaches, to provide better control over particle size, shape, and phase, and will allow scientists to predict where nanoparticles may form within the environment.
Author: Publisher: ISBN: Category : Languages : en Pages : 13
Book Description
Nucleation is a fundamental step in crystal growth. Of environmental and materials relevance are reactions that lead to nucleation of iron oxyhydroxides in aqueous solutions. These reactions are difficult to study experimentally due to their rapid kinetics. Here, we used classical molecular dynamics simulations to investigate nucleation of iron hydroxide/oxyhydroxide nanoparticles in aqueous solutions. Results show that in a solution containing ferric ions and hydroxyl groups, iron-hydroxyl molecular clusters form by merging ferric monomers, dimers, and other oligomers, driven by strong affinity of ferric ions to hydroxyls. When deprotonation reactions are not considered in the simulations, these clusters aggregate to form small iron hydroxide nanocrystals with a six-membered ring-like layered structure allomeric to gibbsite. By comparison, in a solution containing iron chloride and sodium hydroxide, the presence of chlorine drives cluster assembly along a different direction to form long molecular chains (rather than rings) composed of Fe-O octahedra linked by edge sharing. Further, in chlorine-free solutions, when deprotonation reactions are considered, the simulations predict ultimate formation of amorphous iron oxyhydroxide nanoparticles with local atomic structure similar to that of ferrihydrite nanoparticles. Overall, our simulation results reveal that nucleation of iron oxyhydroxide nanoparticles proceeds via a cluster aggregation-based nonclassical pathway.
Author: Jean-Pierre Jolivet Publisher: Oxford University Press ISBN: 0190928123 Category : Science Languages : en Pages : 400
Book Description
This much-anticipated new edition of Jolivet's work builds on the edition published in 2000. It is entirely updated, restructured and increased in content. The book focuses on the formation by techniques of green chemistry of oxide nanoparticles having a technological interest. Jolivet introduces the most recent concepts and modelings such as dynamics of particle growth, ordered aggregation, ionic and electronic interfacial transfers. A general view of the metal hydroxides, oxy-hydroxides and oxides through the periodic table is given, highlighting the influence of the synthesis conditions on crystalline structure, size and morphology of nanoparticles. The formation of aluminum, iron, titanium, manganese and zirconium oxides are specifically studied. These nanomaterials have a special interest in many technological fields such as ceramic powders, catalysis and photocatalysis, colored pigments, polymers, cosmetics and also in some biological or environmental phenomena.
Author: Marta I. Litter Publisher: CRC Press ISBN: 1351334794 Category : Science Languages : en Pages : 324
Book Description
Nanotechnology has a great potential for providing efficient, cost-effective, and environmentally acceptable solutions to face the increasing requirements on quality and quantity of fresh water for industrial, agricultural, or human use. Iron nanomaterials, either zerovalent iron (nZVI) or iron oxides (nFeOx), present key physicochemical properties that make them particularly attractive as contaminant removal agents for water and soil cleaning. The large surface area of these nanoparticles imparts high sorption capacity to them, along with the ability to be functionalized for the enhancement of their affinity and selectivity. However, one of the most important properties is the outstanding capacity to act as redox-active materials, transforming the pollutants to less noxious chemical species by either oxidation or reduction, such as reduction of Cr(VI) to Cr(III) and dehalogenation of hydrocarbons. This book focuses on the methods of preparation of iron nanomaterials that can carry out contaminant removal processes and the use of these nanoparticles for cleaning waters and soils. It carefully explains the different aspects of the synthesis and characterization of iron nanoparticles and methods to evaluate their ability to remove contaminants, along with practical deployment. It overviews the advantages and disadvantages of using iron-based nanomaterials and presents a vision for the future of this nanotechnology. While this is an easy-to-understand book for beginners, it provides the latest updates to experts of this field. It also opens a multidisciplinary scope for engineers, scientists, and undergraduate and postgraduate students. Although there are a number of books published on the subject of nanomaterials, not too many of them are especially devoted to iron materials, which are rather of low cost, are nontoxic, and can be prepared easily and envisaged to be used in a large variety of applications. The literature has scarce reviews on preparation of iron nanoparticles from natural sources and lacks emphasis on the different processes, such as adsorption, redox pathways, and ionic exchange, taking place in the removal of different pollutants. Reports and mechanisms on soil treatment are not commonly found in the literature. This book opens a multidisciplinary scope for engineers and scientists and also for undergraduate or postgraduate students.
Author: Jamie R. Lead Publisher: John Wiley & Sons ISBN: 9781444307498 Category : Science Languages : en Pages : 456
Book Description
An increased understanding of the environmental and human healthimpacts of engineered nanoparticles is essential for theresponsible development of nanotechnology and appropriateevidence-based policy and guidelines for risk assessment.Presenting the latest advances in the field from a variety ofscientific disciplines, this book offers a comprehensive overviewof this challenging, inter-disciplinary research area. Topics covered include: The properties, preparation and applications ofnanomaterials Characterization and analysis of manufacturednanoparticles The fate and behaviour of nanomaterials in aquatic, terrestrialand atmospheric environments Ecotoxicology and human toxicology of manufacturednanoparticles Occupational health and exposure of nanomaterials Risk assessment and global regulatory and policy responses Understanding the behaviour and impacts of nanotechnology in theenvironment and in human health is a daunting task and manyquestions remain to be answered. Environmental and Human HealthImpacts of Nanotechnology will serve as a valuable resource foracademic researchers in nanoscience and nanotechnology,environmental science, materials science and biology, as well asfor scientists in industry, regulators and policy makers.
Author: M. Elimelech Publisher: Elsevier ISBN: 0080513573 Category : Technology & Engineering Languages : en Pages : 459
Book Description
Deposition and aggregation of small solid particles are encountered in many natural and industrial environments. Whether it be deposition of particles onto a surface immersed in a liquid suspension or aggregateion of individual particles, these processes are of enotmous significance. They are vital to the manufacture of magnetic tape, purification of water using packed bed filters, selective capture of solids, cells and macromolecular species, and many other applications. This book presents a unified approach to the measurement, modelling and simulation of these processes, bringing together the disciplines of colliod and surface chemistry, hydrodynamics, and experimental and computational methods. It will be required reading for graduates working in process and environmental engineering, postgraduates involved in industrial R & D and for all scientists wishing to gain a more detailed and realistic understanding of process conditions in these areas.
Author: Damien Faivre Publisher: John Wiley & Sons ISBN: 3527338829 Category : Science Languages : en Pages : 626
Book Description
Alle relevanten Informationen zu Eisenoxiden, von der Struktur und Transformation über Charakterisierungsverfahren bis hin zu den neuesten AnwendungEN. Ein Muss für alle, die in dem Fachgebiet arbeiten.
Author: Patricia Villegas Publisher: ISBN: 9781685070069 Category : Iron oxides Languages : en Pages : 0
Book Description
Iron oxide nanoparticles demonstrate a number of unique properties, including superparamagnetism, biocompatibility, and non-toxicity, which make them an ideal candidate for a variety of applications, as described in this book. Chapter One deals with the recent advances in various synthetic procedures of iron oxide-based nanocomposites, their characterization methods, and their potential applications in energy storage devices, supercapacitors, fuel cells, and more. Chapter Two summarizes current applications of immobilized enzymes based on iron oxide magnetic nanoparticles and discusses future growth prospects. Chapter Three reviews the properties and applications of enzymatic sensors in exploiting tyrosinase, glucose oxidase, and other enzymes for sensing a broad range of biomedical species. Chapter Four discusses magnetic magnetite and maghemite iron oxide nanoparticles from a variety of perspectives. Chapter Five describes how nano iron oxides could be used to remove pollutants from the environment. Chapter Six provides a comprehensive review of the catalytic applications of iron oxide nanoparticles in organic synthesis, high temperature reactions, gas-phase processes, wastewater treatment and supercritical upgradation of heavy petroleum oils. Chapter Seven details the photocatalytic degradation of a class of toxic, aromatic pollutants, namely, phenols and substituted phenols using different types of photocatalysts in the nano size range for effective removal these compounds from water bodies. Lastly, Chapter Eight elucidates various magnetic nanomaterials-based adsorbents used in adsorption techniques for wastewater treatment.
Author: Benjamin Adam Legg
Author: Benjamin Adam Legg
Author: 
Author: Jean-Pierre Jolivet
Author: Marta I. Litter
Author: Jamie R. Lead
Author: Susan Alison Cumberland
Author: M. Elimelech
Author: Damien Faivre
Author: Patricia Villegas
Author: Alan Dole Hewitt