The book highlights the potential use of rare earth ions in enhancing the properties of metal oxides. This book explores the effects of rare earth substitution on the structure and microstructure of metal oxides, exploring their multifunctional applications in energy harvesting, environmental sensing, and remediation. It presents significant improvements in material properties due to rare earth content, providing detailed methodologies for synthesis, advanced characterization techniques, and real-world application examples. The book addresses the growing interest in these materials by offering new research findings and revising foundational principles, making it a crucial guide for those looking to enhance their understanding and application of rare earth-doped nano-metal oxides in sustainable technology solutions. By bridging the knowledge gap, this book provides a unique focus on integrating rare earth elements into nano-metal oxides, showcasing their synergistic potential across energy, sensing, and environmental remediation fields. It offers practical examples and case studies that highlight the latest applications in real-world scenarios, particularly in the environmental and energy sectors. Contributions from interdisciplinary collaborations provides insights into novel methods and hybrid technologies that push the boundaries of current research. This book is an indispensable resource for material scientists, scholars, and researchers working in metal oxide nanomaterials by focusing on the latest advancements and practical applications.
Revolutionizing Material Science: A Thorough Introduction to the
Properties and Innovations of Rare Earth Doped Metal Oxide Nanostructures.-
Influence of Rare Earth Element (REEs) Doping on the Properties of Metal
Oxides.- C Recent Progress of Nanostructured Rare Earth Metals for
Photovoltaic Applications.- Enhanced Adsorption and Degradation of Synthetic
Dyes Using Rare Earth Metal-Doped Biodegradable Polymers.- Role of Artificial
Intelligence and Machine Learning in Rare Earth Doped Metal Oxide
Nanoparticles.- Gas Sensing Technologies for Rare earth-doped metal oxide
nanostructures: Advances in energy harvesting and environmental sensing.-
Computational Modelling of Rare Earth-Doped Nanostructures: Applications in
Energy Harvesting and Environmental Sensing.
Naveen Kumar is currently serving as an Associate Professor in the Department of Physics at Galgotias University, Greater Noida, India. Over the course of his academic and research career, he has made significant contributions to the field of nanomaterials and condensed matter physics, with a particular emphasis on the synthesis, characterization, and application of advanced functional nanostructures. His scientific investigations span a broad range of properties and applications of nanomaterials, including structural, optical, dielectric, magnetic, and electrical properties of metal oxide nanostructures such as ZnO, TiO2, and SnO2.
Virat Khanna is serving as Associate Dean, Research and Development, Chandigarh University, Punjab, India. He is an accomplished academic and researcher with over 15 years of experience in higher education and scientific research. His research contributions span nanotechnology, materials science, and sustainable development.
Nupur Aggarwal is an Associate Professor in the Department of Physics at Chandigarh University, Mohali, India. Her expertise lies in condensed matter physics, with a special focus on dilute magnetic semiconductors, biosynthesized nanomaterials for water treatment and anticancer applications, and dielectric studies of metal oxides for energy storage.
Shalini Tripathi is a Material Scientist III at the Pacific Northwest National Laboratory, Washington, USA, with a strong academic foundation in Materials Science, Catalysis, and Materials Chemistry. She completed her graduation from the prestigious Materials Research Centre at the Indian Institute of Science, India. Her current research focuses on advanced microscopy techniques, contributing to the broader field of Materials Engineering and Nanotechnology.
