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This thesis describes the development and performance of novel photocatalytic inorganic polymer (geopolymer) composites for photodegradation of environmentally harmful organic materials. Nanometer-sized cubic cuprous oxide nanoparticles and spherical Cu2O/TiO2 nano-heterostructures were synthesized via a precipitation method and then added to a metakaolinite-based geopolymer matrix prior to curing at ambient temperature. The morphology of the homogeneous oxide nanoparticle dispersion within the geopolymer matrix was demonstrated by SEM/EDS and HRTEM. FTIR spectroscopy confirmed the formation of a well-reacted geopolymer matrix that was unaffected by the insertion of the Cu2O and Cu2O/TiO2 nanoparticles. The structures of these new composites were determined by 27Al and 29Si MAS NMR spectroscopy. 63Cu NQR spectroscopy and XRD confirmed that the metal oxide nanoparticles are unchanged by their incorporation in the geopolymer composite and after the photodegradation reactions. The nitrogen adsorption-desorption isotherms were determined, providing information about the specific surface areas and total pore volumes of the composites. The action of the composites in the adsorption and photocatalytic destruction of the model organic compound MB was determined under dark and UV illumination conditions. Experiments in dark conditions and under UV irradiation showed that these materials efficiently remove a model organic pollutant (MB dye) from solution by a dual process of adsorption on the geopolymer matrix, and photodecomposition of the dye without destroying the geopolymer structure. The adsorption kinetics of the dye are best described by a pseudo first-order model and the adsorption process by Langmuir-Freundlich isotherms. In a novel extension of this research, the metakaolinite-based geopolymer matrix was modified with a surfactant (cetyltrimethylammonium bromide, CTAB), exploiting the cation exchange capacity of the geopolymers structure. The nano oxide composites w
Renewable Polymers and Polymer-Metal Oxide Composites: Synthesis, Properties, and Applications serves as a reference on the key concepts of the advances of polymer-oxide composites. The book reviews knowledge on polymer-composite theory, properties, structure, synthesis, and their characterization and applications. There is an emphasis on coupling metal oxides with polymers from renewable sources. Also, the latest advances in the relationship between the microstructure of the composites and the resulting improvement of the material’s properties and performance are covered. The applications addressed include desalination, tissue engineering, energy storage, hybrid energy systems, food, and agriculture. This book is suitable for early-career researchers in academia and R&D in industry who are working in the disciplines of materials science, engineering, chemistry and physics. Provides basic principles, theory and synthetic methods of composite materials, polymer composites and metal oxides Reviews the latest advances in polymer-oxide-based applications in medicine, water treatment, energy and sensing Discusses materials from renewable resources, including lifecycle assessment, economic aspects and potential application in tissue engineering, photovoltaics and food packaging
Polymer Composites with Functional Nanoparticles: Synthesis, Properties, and Applications reviews the latest research in the area of polymer nanocomposites and functionalized nanoparticles, providing an introduction for those new to the field, and supporting further research and development. The book helps researchers and practitioners better understand the key role of nanoparticle functionalization for improving the compatibility of inorganic metallic nanomaterials with organic polymers, and for the fabrication of nanostructured materials with special properties. A range of nanoparticles, such as carbon nanotubes are covered, along with descriptions of the methods of functionalization to support better compatibility with polymer matrices. The book also discusses the various applications of this technology, including uses in electronics and the medical and energy industries. Summarizes the latest research in functionalized nanoparticles for modification of polymer matrices, providing a valuable platform for further research Includes functionalization of a range of nanoparticles for incorporation into nanocomposites, including carbon nanotubes, graphene, gold and silver, silica and clay Provides detailed coverage of application areas, including energy, electronics, biomedical applications, and end-of-life considerations
New Polymer Nanocomposites for Environmental Remediation summarizes recent progress in the development of materials’ properties, fabrication methods and their applications for treatment of contaminants, pollutant sensing and detection. This book presents current research into how polymer nanocomposites can be used in environmental remediation, detailing major environmental issues, and key materials properties and existing polymers or nanomaterials that can solve these issues. The book covers the fundamental molecular structure of polymers used in environmental applications, the toxicology, economy and life-cycle analysis of polymer nanocomposites, and an analysis of potential future applications of these materials. Recent research and development in polymer nanocomposites has inspired the progress and use of novel and cost-effective environmental applications. Presents critical, actionable guidelines to the structure and property design of nanocomposites in environmental remediation Focuses on taking technology out of the lab and into the real world Summarizes the latest developments in polymer nanocomposites and their applications in catalytic degradation, adsorptive removal and detection of contaminants in the environment Enables researchers to stay ahead of the curve, with a full discussion of regulatory issues and potential new applications and materials in this area
Polymers are used in practically every facet of daily life. Most polymers come from fossil fuels and are not biodegradable, causing long-term environmental hazards. Biodegradable polymers provide an alternative, environmentally friendly class of materials. Composites of such polymers have high potential within a wide spectrum of applications.
The inorganic titanium dioxide TiO2 and metal-free graphitic carbon nitride (g-C3N4) are the two most important photocatalysts owing to their low cost, non-toxicity, high thermal and chemical stability, as well as high reactivity. However, these two materials also suffer from certain drawbacks such as a relatively high rate of electron-hole pair recombination, a slightly large bandgap that requires UV-light for activation (TiO2), and a relatively small surface area (g-C3N4).This thesis focuses to overcome above drawbacks by combining TiO2 with low bandgap metal chalcogenide semiconducting nanoparticles as a strategy to create an efficient charge separation at the interface of the heterojunctions and to extend the absorption to visible region. This thesis also attempts to improve the photocatalytic efficiency of g-C3N4 by synthesizing it with high surface area and, finely, by combining it with TiO2. After describing briefly the motivation behind the work and the existing literature on the subject matter in the first chapter, the Chapter 2 describes precursor-mediated synthesis and photocatalytic activity of binary coinage metal chalcogenide nanoparticles and their composites with TiO2 under mild conditions. We successfully isolate and characterize kinetically and/or thermally unstable molecular species during the reactions, thus providing an insight into the molecule-to-nanoparticle mechanisms. The metal chalcogenide-titania nanocomposites show superior activity for the photodegradation of formic acid under ultraviolet light, as compared to titania (P25), which is a well-established benchmark for photocatalysis under UV light. Chapter 3 describes the synthesis of ternary coinage metal chalcogenides and their composites with titania. A direct room temperature reaction of tBu2Se with copper and silver trifluoroacetates gives copper-silver-selenide nanoparticles that are formed via a highly reactive intermediate molecular species [Ag2Cu(TFA)4(tBu2Se)4]. We also employed the pre-formed copper chalcogenide NPs as precursors and reacted it with di-tertiary butyl chalcogenide to obtain ternary metal chalcogenide nanoparticles and their composites with TiO2 in pure phase and with high yield. Photocatalytic studies for the degradation of formic acid under ultraviolet radiations show that the ternary CuAgSe-TiO2 nanocomposites are even better photocatalysts than the binary chalcogenide-TiO2 nanocomposites described in Chapter 2. The second part of this thesis described in Chapter 4 diverges from the earlier chapters to concentrate on the coupling of titania with graphitic carbon nitride. In the first step, we develop a simple single-step calcination approach to synthesize graphitic nanoparticles with a high surface area (200 m2/g). We test the prepared photocatalyst for the degradation of formic acid and phenol under visible light, and analyze the effect of factors such as surface area, irradiance and concentration of carbon nitride on the photocatalytic performance. Results show that the performance increases linearly with surface area and irradiance, whereas it first increases and gradually reaches plateau as concentration of the photocatalyst is increased. In the second step, we couple carbon nitride with titania using mechanical mixing. The prepared nanocomposites are then evaluated for the photodegradation of formic acid under both ultraviolet and visible lights. Finally, the Chapter 5 describes the experimental details of the synthesis and characterization of the molecular precursors, metal chalcogenide nanoparticles, g-C3N4 nanosheets as well as their composites with TiO2. It also describes in detail the experimental setup for the photocatalytic studies.
This book provides an overview on the latest advances in the synthesis, properties and applications of polymeric eco-composites and eco-nanocomposites reinforced natural fibers (e.g. pulp-fiber, flax, etc.) and nanofillers (e.g. organoclay, nano-SiC, etc.). Potential challenges and future directions of these composites are highlighted and addressed. This book offers numerous graphs and electron micrographs for easy understanding by students, researchers and practicing engineers.
This book contains precisely referenced chapters, emphasizing environment-friendly polymer nanocomposites with basic fundamentals, practicality and alternatives to traditional nanocomposites through detailed reviews of different environmental friendly materials procured from different resources, their synthesis and applications using alternative green approaches. The book aims at explaining basics of eco-friendly polymer nanocomposites from different natural resources and their chemistry along with practical applications which present a future direction in the biomedical, pharmaceutical and automotive industry. The book attempts to present emerging economic and environmentally friendly polymer nanocomposites that are free from side effects studied in the traditional nanocomposites. This book is the outcome of contributions by many experts in the field from different disciplines, with various backgrounds and expertises. This book will appeal to researchers as well as students from different disciplines. The content includes industrial applications and will fill the gap between the research works in laboratory to practical applications in related industries.
This book examines the current state of the art, new challenges, opportunities, and applications in the area of polymer nanocomposites. Special attention has been paid to the processing-morphology-structure-property relationship of the system. Various unresolved issues and new challenges in the field of polymer nanocompostes are discussed. The infl