Bøger i Nanostructure Science and Technology serien

This book addresses the manufacturing methods, characteristic tubular morphologies, diverse functions, and potent applications of organic tubular architectures prepared or self-assembled from rationally designed molecular building blocks.

This book covers the remarkable progress in the field of electrospun nanofibrous materials synthesis that has been made in recent years for clean water production. The goal is to offer comprehensive and substantial contents in each chapter, entailing the electrospinning principle, novel materials and methods, properties, characterization, and applications, such as adsorption, catalysis, and membranes. The book is instrumental in terms of showing the scale-up production of desired fibers that ensure the control of the structure¿properties relationship for developing effective water treatment technologies. Every chapter ends with a special section for highlighting research challenges and breakthroughs, so that scientists can explore these opportunities and discover new directions for future developments. Material scientists, nanotechnologists, chemists, engineers, water specialists, and environmentalists will be inspired by the information on electrospun nanofibrous materials tobe found in the book. The wide variety of new ideas and recommended future reading will encourage early-career scientists working in this field to design new experiments and practices. The book is useful for college and university-level students enrolled in project courses in materials science and related fields.

This book introduces high-temperature shock technology (HTS), a new method for ultra-fast synthesis of nanomaterials. HTS cannot only effectively avoid surface oxidation, agglomeration and immiscibility during the preparation of nanomaterials but also eliminate the defects or impurities of carbon-based nanomaterials. The book first presents the unique working devices of HTS. Then, it explains the working principle of its rapid heating and cooling rate at the millisecond level. In addition, the book highlights the latest research achievements of this technology in catalysis, batteries, carbon materials and new material devices, and puts forward the cost-benefit analysis and future development direction. Given its scope, the book appeals to a broad readership, particularly researchers engaged in materials, chemistry, new energy and other related fields, as well as teachers of relevant majors in colleges and universities.

This contributed volume provides a comprehensive understanding of synthetic protocols, characterization techniques, and current applications of iron oxide-based nanocomposite and nanoenzyme materials. It covers basic concepts and recent advancements in iron oxide-based nanocomposites and nanoenzymes, focusing on their synthesis, characterization, and functionalization for specific research applications. The different chapters in the book highlight key characterization techniques including Fourier Transform Infrared Spectroscopy, X-ray diffraction, Scanning Electron Microscopy, and Transmission Electron Microscopy, among others while it also explores various applications of these materials, such as adsorption of heavy metals and dyes, gas sensors, biomedical applications, photo-catalysis, and photovoltaic sensors. This book serves as a valuable resource for researchers and graduate students working in the fields of materials science, chemistry, physics, and biotechnology.