This concise and systematically organized text, now in its second edition, gives a clear insight into various membrane separation processes. It covers the fundamentals as well as the recent developments of different processes along with their industrial applications and the products. It includes the basic principles, operating parameters, membrane hardware, flux equation, transport mechanism, and applications of membrane-based technologies.
membrane separation process by kaushik nath pdf 13
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Membrane separation processes are largely rate-controlled separations which require rate analysis for complete understanding. Moreover, a higher level of mathematical analysis, along with the understanding of mass transfer, is also required. These are amply treated in different chapters of the book to make the students comprehend the membrane separation principles with ease. This textbook is primarily designed for undergraduate students of chemical engineering, biochemical engineering and biotechnology for the course in membrane separation processes. Besides, the book will also be useful to process engineers and researchers.
KAUSHIK NATH (Ph.D., IIT Kharagpur) is Professor and Head, Department of Chemical Engineering, G.H. Patel College of Engineering and Technology, Vallabh Vidyanagar, Gujarat. He has more than 18 years of teaching and research experience. His major research interests include advanced separation processes, biochemical engineering and wastewater treatment. He has authored 74 research articles in various international and national journals, conference proceedings and contributed 5 book chapters.
Anirban Roy, PhD, is an Assistant Professor in the Department of Chemical Engineering at BITS Pilani Goa campus. He designs processes for water treatment for applications like industrial wastewater and greywater and has a startup through which he develops membrane-based technologies for both water as well as for biomedical device applications. He has published 14 articles in journals of international repute, filed five patents, and published a book on hemodialysis. Siddhartha Moulik, PhD, is currently working in and has experience across multiple areas, including chemical engineering, biomass, water management, and others. He has been associated with various industrial sponsored projects for organizations such as TATA Steel, Dr. Reddy's Laboratories, and Tata Chemicals Ltd. He has published 16 articles in international scientific journals, filed one patent, published one book, Membrane Processes, also available from Wiley-Scrivener, and ten book chapters. He is also the recipient of 12 prestigious awards. Reddi Kamesh, PhD, is a scientist with the Process Engineering and Technology Transfer Dept., CSIR-IICT, Hyderabad, India. He has authored one book chapter and over 40 papers in peer-reviewed international journals and proceedings of conferences. He has been the recipient of the Ambuja Young Researchers Award from Indian Institute of Chemical Engineers (IIChE). Aditi Mullick, PhD, did her dissertation in wastewater engineering, and her area of research includes the application of novel and sustainable environment friendly routes for water treatment related to organic and inorganic pollutant degradation. She has published seven articles in international journals, filed one patent, and published one book. She is also the recipient of five prestigious national awards and fellowship. Permissions Request permission to reuse content from this site
This research gave a new dimension to microalgae cultivation using nanoemulsion composed of two different oils. In the future, other potential biocompatible oils can be explored for increasing the biomass of microalgae. The next step would be to test it with actual sources of CO2 such as flue gas. Recyclability of nanoemulsions could also save cost and energy. Energy recovered by recycling the emulsion can be compared with energy given during the centrifugation of the nanoemulsion extraction process. These energy calculations can help to define a scale for nanoemulsion-based technology. Secondly, less energy-intensive nanoemulsion separation technology from microalgal biomass could help to scale this process. 2ff7e9595c
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