Nanofluids for Efficient Energy Conservation and Process Intensification presents mathematical, numerical, and experimental methodologies of applying nanofluids in renewable and non-renewable energy conservation and process intensification. It explores the mechanisms for developing high-performance heat transfer and mass transfer hybrid nanofluids.
Beginning with thermophysical and optical properties enhancement of nanofluids, the book covers nanoparticle synthesis, stabilization techniques, and life-cycle assessment (LCA). It delves into the use of ionanofluids in environmental remediation, hybrid nanofluids for carbon capture, and the role of nanofluids in solar thermal systems. The book also discusses innovative modeling and optimization methods, such as the use of Response Surface Methodology (RSM) and Artificial Neural Networks (ANN) to facilitate predictive modeling of nanofluid performance.
Researchers, graduate students, and industry practitioners studying the advances in applications of nanofluids within mechanical and chemical engineering will find this book a useful resource.
Table of Contents:
1. Introduction to Nanofluids for Efficient Energy Conservation and Process Intensification. 2. Ionanofluids for Environmental Remediation. 3. Hybrid Nanofluids for Carbon Capture. 4. Hybrid Nanofluids for Renewable and Sustainable Energy. 5. Mathematical Modelling of Hybrid Nanofluids and Applications for Energy Conservation. 6. Mathematical Modelling of Ionanofluids and Applications for Energy Conservation. 7. Molecular Dynamics Study of Nanofluid Applications. 8. Life Cycle Assessment of Nanofluids Application in Process Industries. 9. Nanofluids in Thermal Management and Heat Recovery Systems. 10. Nanofluids in Intensification of Process Industry. 11. Nanofluids for Enhanced Solar Collector Efficiency. 12. Study of Emulsion Nanofluid Membrane. 13. RSM and ANN Studies for the Intensification of Nanofluid Application. 14. Future Prospects of Nanofluid Applications for Energy Conservation.
About the Author :
Dr. Shriram S. Sonawane is a Professor of Chemical Engineering at Visvesvaraya National Institute of Technology (VNIT), Nagpur, India. With over two decades of academic and research experience, he has made pioneering contributions in the fields of polymer nanocomposites, nanofluids, nano-separation technology, and process modelling and simulation. He has published more than 250 research papers in various national and international journals of repute and has over 12 patents to his credit. He is also the author of 4 books, editor of 5 books, and has contributed more than 50 book chapters. Dr. Sonawane is a Fellow of the Maharashtra Academy of Sciences and the Indian Institute of Chemical Engineers (IIChE). He has been nominated twice for the prestigious Shanti Swarup Bhatnagar Award.
Dr. Parag Thakur is an Assistant Professor at SVNIT, Surat, India. He previously served as an ad-hoc faculty at NIT, Warangal. Following the completion of his Ph.D. at VNIT, Nagpur, India, he has been invited to conduct his Postdoc research at Chonnam National University, South Korea. His research areas include nanofluids, micro-fluids, nanocomposites, and modeling and simulation. Dr. Thakur has published 36 book chapters, 2 books, 3 patents, and 15 articles in reputed journals, receiving more than 800 citations for his research. He has attended over 50 international conferences, where he received several best presentation awards. He also serves as a reviewer for the Journal of Mass and Heat Transfer and Separation Science and Technology.
Dr. Manjakuppam Malika is an Assistant Professor in the Department of Chemical Engineering, BV Raju Institute of Technology, Narsapur, Telangana, India. Her current research focuses on nanofluid applications in chemical engineering and technology. Dr. Malika has published 25 research articles in reputed journals as well as 20 book chapters, 3 books, and 3 patents. She has received more than 800 citations for her work.
