Nanotechnology for Oil-Water Separation: From Fundamentals to Industrial Applications explores how nanotechnologically engineered solutions (modified meshes, carbon nanotubes, functionalized fabrics, textile or hybrid elements for bio-membranes, nanofibrous materials, and many more) can be used to remediate current damage to the environment for a better tomorrow. Design and fabrication of low-cost, effective and environmentally friendly micro/nanomaterials exhibiting strong wettability properties and mechanical and chemical stability are examined, along with current research developments and possible future directions, making this book an essential read for researchers, advanced students, and industry professionals with an interest in nanotechnology and sustainable (bio)technologies. The increasing amounts of industrial substances released by petrochemical, steel or gas-generating plants and food-processing factories into water poses an ever more serious environmental threat. Due to the significant adverse impact on the natural ecosystem, aquatic organisms and human health, the scientific community has made its priority to find sustainable methods to separate oil-water mixtures.

Nano-Bioremediation: Fundamentals and Applications explores how nano-bioremediation is used to remedy environmental pollutants. The book's chapters focus on the design, fabrication and application of advanced nanomaterials and their integration with biotechnological processes for the monitoring and treatment of pollutants in environmental matrices. It is an important reference source for materials scientists, engineers and environmental scientists who are looking to increase their understanding of bioremediation at the nanoscale. The mitigation of environmental pollution is the biggest challenge to researchers and the scientific community, hence this book provides answers to some important questions. As an advanced hybrid technology, nano-bioremediation refers to the integration of nanomaterials and bioremediation for the remediation of pollutants. The rapid pace of urbanization, massive development of industrial sectors, and modern agricultural practices all cause a controlled or uncontrolled release of environmentally-related hazardous contaminants that are seriously threatening every key sphere, including the atmosphere, hydrosphere, biosphere, lithosphere, and anthroposphere.

Biodegradation and Biodeterioration at the Nanoscale describes the biodegradation and biodeterioration of materials in the presence of nanomaterials. The book's chapters focus on the basic principles, action mechanisms and promising applications of advanced nanomaterials, along with their integration with biotechnological processes for controlled degradation and deterioration of materials. In addition, the current research indications, positive or negative environmental impacts, legislation and future directions are also discussed. This book is an important reference source for researchers, engineers and scientists working in environmental remediation, biotechnology, materials science, corrosion and nanotechnology.

MXene-based Hybrid Nano-Architectures for Environmental Remediation and Sensor Applications: From Design to Applications brings together the state-of-the-art in molecular design, synthetic approaches, unique properties, and applications of MXene-based hybrid nanomaterials, which combine 2D MXenes with low dimensional materials and open the door to novel solutions in environmental remediation, sensing, and other areas. The book begins by introducing the fundamentals of MXenes and MXene-based hybrid nano-architectures, including synthesis methods, structural design, basic properties, and characterization techniques. The second section of the book provides in-depth coverage of specific areas of environmental remediation and removal, covering gases, toxic heavy metals, organic pollutants, pharmaceuticals, organic dyes, pesticides, and inorganic pollutants. This is followed by a section focusing on targeted sensing applications, including electrochemical sensors, optical sensors, biosensors, and strain sensors. The final chapters consider other application areas for MXene-based hybrid nano-architectures, such as wearable devices and thermal energy storage, and address the other key considerations of secondary environmental contamination, toxicity, regeneration and re-use of MXenes, and future opportunities. This is a valuable resource for researchers and advanced students across nanotechnology, environmental science, biotechnology, chemistry, and materials science and engineering, as well as industrial scientists, engineers, and R&D professionals with an interest in MXenes and advanced nanomaterials for a range of advanced applications, notably in environmental remediation and sensing.

Bionanocatalysis: From Design to Applications discusses recent advances in nano-biocatalysis, fundamental design concepts and their applications in a variety of industry sectors. Strategies for immobilizing enzymes onto nanocarriers, made from polymers, silicas, carbons, and metals, by physical adsorption, covalent binding, cross-linking, or specific ligand spacers are also discussed as are the advantages, problems and solutions derived from the use of non-porous nanomaterials for enzyme immobilization. This is an important reference source for materials scientists and chemical engineers who would like to learn more about how nanobiocatalysts are designed and used. Biocatalysis has emerged as a sustainable technique to synthesize valuable commodity chemicals with wide applications in various industrial domains, such as in agriculture, cosmetics, pharmaceuticals, biofuels, biosensors, biofuel cells, biochemicals, and foods. The synergistic integration of bio-catalysis engineering with nanostructured materials, as unique multifunctional carrier matrices, has emerged as a new interface of nano-biocatalysis (NBC).