The book focuses on the intersection of nanoscience, green energy, and environmental sustainability, exploring the development and application of nanostructured materials, energy storage and conversion technologies, renewable energy systems, and environmental remediation methods. It delves into sustainable nanomanufacturing, green nanotechnology, and the nano-energy-environment nexus, highlighting the potential of nanoscience to address global energy and environmental challenges. By covering the broad range of topics in field of nanoscience, green energy and environmental sustainability, this book also explores the sustainability and scalability of nanotechnology-based solutions, with a focus on developing environmentally friendly and cost-effective methods for producing nanostructured materials. By bridging the gap between nanoscience, green energy, and environmental sustainability, this project aims to provide a comprehensive framework for addressing global energy and environmental challenges. The book aims to provide a comprehensive resource for researchers, policymakers, and industry professionals working towards a more sustainable future. With a focus on real-world impact, the book includes case studies and examples showcasing how nanoscience is contributing to clean energy and environmental protection. It serves as a valuable resource for researchers, academics, industry professionals, and students, encouraging collaboration and further advancements in the field. By reading this book, readers gain a deeper understanding of the potential of nanotechnology to address some of the world's most pressing environmental challenges. This book is written in an accessible way, making it suitable for readers from a variety of backgrounds, including students, researchers, policymakers, and industry professionals.

Focuses on nanotechnology and sustainability lack a comprehensive overview of the field Is needed to capture the latest advancements and trends in the field Provides sustainability and environmental applications of nanotechnology require an interdisciplinary approach

Autorentext

Dr. Dharmendra Tripathi has been working as an associate professor in the Department of Mathematics, National Institute of Technology, Uttarakhand. Prior to joining NIT Uttarakhand, he has worked in various reputed institutions like Manipal University Jaipur, NIT Delhi, IIT Ropar and BITS Pilani Hyderabad. He completed his PhD in 2009 from Indian Institute of Technology BHU and M.Sc. in Mathematics from Banaras Hindu University. His research work is focused on the mathematical modelling and simulation of biological flows in deformable domains, Peristaltic flow of Newtonian and non-Newtonian fluids, Membrane-Based Pumping Flow Models; Dynamics of various infectious diseases; microfluidics; CFD, Biomechanics; Heat Transfer; Nanofluids; Energy Systems; Numerical methods; etc. He has supervised 09 Ph.D. students and 06 are working under his supervision. He has also guided various UG & PG projects.
Dr. Jagrati Sahariya, is working as an associate professor, in Department of Physics, National Institute of Technology, Uttarakhand. She is having teaching experience of more than 13 years. Dr. Sahariya has been working in the field of -ray scattering and band structure calculations since last 13 years. She has received her Ph.D. degree in 2012 in the field of electronic structure calculation and Compton scattering. As a part of her Ph.D. thesis, she has studied electronic and magnetic properties of a variety of technological important materials. Dr. Sahariya has sufficient expertise in using different band structure methods like full potential linearized augmented plane wave, linear combinations of atomic orbitals and spin polarized relativistic Korringa-Kohn-Rostoker to compute electronic structure, optical and magnetic properties and Compton profiles of variety of materials. She has published more than 100 papers in peer reviewed international journals of high impact factor and repute conferences proceedings.
Dr. Kamal Nayan Sharma serves as an assistant professor of Chemistry at the Amity School of Applied Sciences, Amity University Haryana, Gurugram. He is a recipient of multiple prestigious research fellowships, including the International Research Experience (SIRE) Fellowship awarded by the SERB, Government of India. As part of this fellowship, he was deputed to the University of Waikato, New Zealand, where he pursued a six-month research collaboration with Associate Professor Dr. Graham C. Saunders. Recently, Dr. Sharma has also been awarded the SERB-TARE (Teachers Associateship for Research Excellence) Fellowship, with the Central University of Rajasthan serving as the host institution. Prior to joining Amity University, Dr. Sharma held a faculty position at Vivekananda Global University, Jaipur. He obtained his Ph.D. from the IIT Delhi and later led a SERB-sponsored Startup Research Grant for Young Scientist (YSS) at MNIT Jaipur as Principal Investigator.
Prof. Dr. Amit Soni is currently working a professor, Department of Electrical Engineering, Manipal University Jaipur. He did his BE Electrical (Electronics & Power) Engineering from SRTMU, Nanded, Maharashtra, in 2001, scoring first rank and was awarded Gold Medal for his outstanding academic performance. He has done M.Tech. (Power System) in 2005 and Ph.D. (Power System) in 2012, both from Malaviya National Institute of Technology Jaipur (MNIT), Jaipur. He has a rich Academic and Research experience of 24 years which includes 3 years of Industrial experience in RRVPNL, Jaipur. He is currently working as Registrar, Manipal University Jaipur and has held various key administrative positions in his career at Manipal University Jaipur. Before joining Manipal University Jaipur, he has worked as Director, Asians Institute of Technology (AIT), Rajasthan, Coordinator Global College of Technology (GCT), and HOD, Department of Electrical Engineering, Global Institute of Technology (GIT).

Inhalt

1. Nanoscience for a Greener Future.- 2. Fundamentals of Nanoscience for Sustainability.- 3. Visible Light Active Plasmonic Metal-Semiconductor Nanocomposites for Efficient Green Hydrogen Production.- 4. Nanomaterials in Energy Conversion and Storage.- 5. Green Hydrogen Production using Nanotechnology.