• Explores novel membrane materials and systems from preparation methods, materials selection, and their application in monitoring, fouling control, and performance enhancement. • Examines the mechanism of fouling prevention and cleaning in various electrically conductive materials. • Evaluates the scalability of antifouling materials and coatings, as well as electrically enhanced processes for monitoring and control in membrane separation technology • Assesses advantages and limitations of applying electrically conductive membrane systems to fouling control for specific water treatment applications. • Provides a critical review of scientific literature in the specialized area of electrical conductive materials and systems for membrane technology.

Reveals insights into industry trends and breakthroughs advances in the area of nanofiltration membrane technology Includes case studies that highlight and real-world applications of nanofiltration technology in various related industries such as textile, oil and gas, and agriculture. Assesses the advantages, limitations, and future prospects of nanofiltration technology through illustrations and examples.

Membranes play a crucial role in ensuring the optimum use and recovery of materials in manufacturing. In the process industries, they are required for efficient production and minimization of environmental impact. They are also essential for the efficient production of clean water, a significant global issue. Membrane Fabrication brings together experts from various disciplines who discuss current membrane fabrication methods and how they are used in the optimization of membrane applications. They present innovative ideas on the development of membrane science and technology with a view toward efficient application of membrane separation processes. Exploring fabrication processes for polymeric, inorganic, and composite membranes, the book details the effects of different fabrication conditions and how these conditions can be controlled to optimize membrane construction and the subsequent application of the membrane system. It examines the advantages and disadvantages of each type of membrane, including the malleable yet vulnerable polymeric membranes, the robust yet costly inorganic membranes, and composite membranes, constructed with a blend of inorganic and organic materials. Offering a comprehensive survey of a range of fabrication methods, the book is essential reading for those engaged in the R & D activities of the field, as well as those interested in the sustainable development of membranes for various applications. It is also an important resource for industrialists and others charged with developing and introducing membrane processes into production or waste management.

This book focuses on the nanofiber membrane's fabrication, characterization, and performance for medical, environment and energy applications. Topics include polymer, inorganic and composite-form nanofiber membrane materials. Top Research teams from varied disciplines and continents outline applied nanofiber membrane fabrication techniques and characterizations. Promising nanofiber membranes for improving and enhancing technologies used in drug delivery, wound healing, tissue engineering, water and wastewater treatment and purification, gas separation and purification, air purification, and fuel cells are discussed along with the likely path forward for commercial usage. Key Features: Shares the most recent discovery solutions from experts all over the globe for the numerous problems in medical, environmental and energy applications. Provides a holistic cycle of nanofiber membrane development which comprehensively discusses the membrane preparation, characterizations, performance and the way forward for a specific process and application. Explains the mechanism of separation and purification. Focuses on the nanofiber membrane's fabrication, characterizations, and performance in various scenarios and commercial applications.

Membranes play a crucial role in ensuring the optimum use and recovery of materials in manufacturing. In the process industries, they are required for efficient production and minimization of environmental impact. They are also essential for the efficient production of clean water, a significant global issue. Membrane Fabrication brings together experts from various disciplines who discuss current membrane fabrication methods and how they are used in the optimization of membrane applications. They present innovative ideas on the development of membrane science and technology with a view toward efficient application of membrane separation processes. Exploring fabrication processes for polymeric, inorganic, and composite membranes, the book details the effects of different fabrication conditions and how these conditions can be controlled to optimize membrane construction and the subsequent application of the membrane system. It examines the advantages and disadvantages of each type of membrane, including the malleable yet vulnerable polymeric membranes, the robust yet costly inorganic membranes, and composite membranes, constructed with a blend of inorganic and organic materials. Offering a comprehensive survey of a range of fabrication methods, the book is essential reading for those engaged in the R & D activities of the field, as well as those interested in the sustainable development of membranes for various applications. It is also an important resource for industrialists and others charged with developing and introducing membrane processes into production or waste management.

Membrane-Based Salinity Gradient Processes for Water Treatment and Power Generation focuses on the various types of membrane- based salinity gradient processes that can be applied for desalination. Topics cover salinity gradient processes for desalination, such as Forward Osmosis (FO) and Pressure Retarded Osmosis (PRO), with chapters selected exclusively from a number of world-leading experts in various disciplines and from different continents. Sections include discussions on the theoretical and fundamental approaches to salinity gradient processes, various types of membrane materials and development, i.e., flat sheet and hollow fiber, various salinity water sources for an economically feasible process, and large-scale applications. Finally, the book focuses on economically feasible process optimization when both operational and capital costs are considered.

Membrane Characterization provides a valuable source of information on how membranes are characterized, an extremely limited field that is confined to only brief descriptions in various technical papers available online. For the first time, readers will be able to understand the importance of membrane characterization, the techniques required, and the fundamental theory behind them. This book focuses on characterization techniques that are normally used for membranes prepared from polymeric, ceramic, and composite materials.

Membrane Modification: Technology and Applications is written for engineers, scientists, graduate students, and researchers in the field of membrane science and technology, materials science, applied physics, chemistry, and environmental science. The book presents the complete range of membrane modification techniques used to increase efficiency of membrane processes. The book starts with an examination of the use of membrane modification to optimize the performance of membranes used in industry. It concludes by demonstrating how membrane modification can improve separation processes in industrial sectors that are recognized as global polluters of water sources.
Features

• Illustrates the use of Electrochemical Impedance Spectroscopy (EIS) in the characterization of commercial and novel membranes
• Overviews various surface modification techniques applied to enhance the bulk and surface properties of nanofiber membranes
• Covers the factors affecting membrane fouling and the use of nanoparticles in membrane modification processes
• Explores the use of plasma treatment for the modification of polymeric membranes

Written by professors, engineers, and researchers in the field, the book covers recent advances and comprehensively describes novel and most-used membrane characterization techniques. Modification of different materials and geometrics include flat-sheet, hollow-fiber, and nano-fiber membranes as well as different membrane processes such as reverse osmosis, membrane distillation, gas separation, pervaporation, and membrane fuel cells. Chapters contain tables, figures, photographs, and theoretical equations to aid with reader comprehension.

This book focuses on the nanofiber membrane's fabrication, characterization, and performance for medical, environment and energy applications. Topics include polymer, inorganic and composite-form nanofiber membrane materials. Top Research teams from varied disciplines and continents outline applied nanofiber membrane fabrication techniques and characterizations. Promising nanofiber membranes for improving and enhancing technologies used in drug delivery, wound healing, tissue engineering, water and wastewater treatment and purification, gas separation and purification, air purification, and fuel cells are discussed along with the likely path forward for commercial usage. Key Features: Shares the most recent discovery solutions from experts all over the globe for the numerous problems in medical, environmental and energy applications. Provides a holistic cycle of nanofiber membrane development which comprehensively discusses the membrane preparation, characterizations, performance and the way forward for a specific process and application. Explains the mechanism of separation and purification. Focuses on the nanofiber membrane's fabrication, characterizations, and performance in various scenarios and commercial applications.

Osmosis Engineering provides a comprehensive overview of the state-of-the-art surrounding osmosis-based research and industrial applications. The book covers the underpinning theories, technology developments and commercial applications. Sections discuss innovative and advanced membranes and modules for osmosis separation processes (e.g., reverse osmosis, forward osmosis, pressure retarded osmosis, osmotic membrane distillation), different application of these osmosis separation processes for energy and water separation, such as the treatment of radioactive waste, oily wastewater and heavy metal removal, draw solutions, pretreatment technologies, fouling effects, the use of renewable energy driven osmotic processes, computational, environmental and economic studies, and more.

This is the first book to bring together both the basic theory and proven process engineering practice of AFM. It is presented in a way that is accessible and valuable to practising engineers as well as to those who are improving their AFM skills and knowledge, and to researchers who are developing new products and solutions using AFM.

The book takes a rigorous and practical approach that ensures it is directly applicable to process engineering problems. Fundamentals and techniques are concisely described, while specific benefits for process engineering are clearly defined and illustrated. Key content includes: particle-particle, and particle-bubble interactions; characterization of membrane surfaces; the development of fouling resistant membranes; nanoscale pharmaceutical analysis; nanoengineering for cellular sensing; polymers on surfaces; micro and nanoscale rheometry.
Atomic force microscopy (AFM) is an important tool for process engineers and scientists as it enables improved processes and productsThe only book dealing with the theory and practical applications of atomic force microscopy in process engineeringProvides best-practice guidance and experience on using AFM for process and product improvement