Introducing the fields of nanomaterials and devices, and their applications across a wide range of academic disciplines and industry sectors, Donglu Shi takes an approach that provides a bridge between the knowledge acquisition and practical work, providing a starting point for the research and development of applications.

The major areas covered in this book are: - The characterization of nanomaterials, their preparation methods and performance testing techniques - The design and development of nano-scale devices - The applications of nanomaterials, with examples taken from different industry sectors, such as lighting, energy, bioengineering and medicine / medical devices. Key nanomaterial types are covered, such as carbon nanotubes, nanobiomaterials, nano-magnetic materials, semiconductor materials and nanocomposites. Shi also provides detailed coverage of key emerging technologies such as DNA nanotechnology and spintronics. This resulting text is equally relevant for advanced students (senior and graduate) and for engineers and scientists from a variety of different academic backgrounds working in the multi-disciplinary field of nanotechnology.

Provides detailed guidance for the characterization of nanomaterials, their preparation, and performance testing. Explains the principles and challenges of the design and development of nano-scale devices Explores applications through cases taken from a range of different sectors, including electronics, energy and medicine.

NanoScience in Biomedicine provides up-to-date information in the frontier fields of nano biomedicine focusing on basic concepts and recent developments in many topical areas including particular nanomaterials synthesis, field emission of carbon nanotubes, flexible dye-sensitized nano-porous films, magnetic nanofluids, and intrinsically electroconducting nanoparticles. Novel methods of synthesizing nanoscale biomaterials and their applications in biomedicine are also included such as nano-sized materials for drug delivery, bioactive molecules for regenerative medicine, nanoscale mechanisms for assembly of biomaterials, and nanostructured materials constructed from polypeptides. This book is organized in three parts: Part I introduces most recent developments in all aspects of design, synthesis, properties, and applications of nanoscale biomaterials. Part II focuses on novel nanotechnologies in biomedicine. Part III includes some of the new developments of nanomaterials synthesis and recent studies on nanostructure-properties relationships. The book comprehensively addresses the most critical issues in a tutorial manner so that technical non-specialists and students in both biomedical sciences and engineering will be able to benefit. All chapters are contributed by internationally recognized scholars.

Dr. Donglu Shi is a professor at the Chemical and Materials Engineering Department, University of Cincinnati, USA."

This book provides an up-to-date introduction to the field of functional thin films and materials, encompassing newly developed technologies and fundamental new concepts. The focus is on the critical areas of novel thin films such as sol gel synthesis of membrane, ferroelectric thin films and devices, functional nanostructured thin films, micromechanical analysis of fiber-reinforced composites, and novel applications. An important aspect of the book lies in its wide coverage of practical applications. It introduces not only the cutting-edge technologies in modern industry, but also unique applications in many rapidly advancing fields. This book is written for a wide readership including university students and researchers from diverse backgrounds such as physics, materials science, engineering and chemistry. Both undergraduate and graduate students will find it a valuable reference book on key topics related to solid state and materials science.

The current interest in developing novel materials has motivated an increasing need for biological and medical studies in a variety of dinical applications. Indeed, it is dear that to achieve the requisite mechanical, chemical and biomedical properties, especially for new bioactive materials, it is necessary to develop novel synthesis routes. The tremendous success of materials science in developing new biomaterials and fostering technological innovation arises from its focus on interdisciplinary research and collaboration between materials and medical sciences. Materials scientists seek to relate one natural phenomenon to the basic structures of the materials and to recognize the causes and effects of the phenomena. In this way, they have developed explanations for the changing of the properties, the reactions of the materials to the environment, the interface behaviors between the artificial materials and human tissue, the time effects on the materials, and many other natural occurrences. By the same means, medical scientists have also studied the biological and medical effects of these materials, and generated the knowledge needed to produce useful medical devices. The concept of biomaterials is one of the most important ideas ever generated by the application of materials science to the medical field. In traditional materials research, interest focuses primarilyon the synthesis , structure, and mechanical properties of materials commonly used for structural purposes in industry, for instance in mechanical parts of machinery.

This book focuses on the investigation of the basic properties of magnetic nanostructures, and the fundamental physics of novel nanostructures for submicron devices. It provides a broad overview of the latest developments in this emerging and fascinating field of nano-sized materials, with emphasis on the practical understanding and operation of devices using or based on nanostructured magnetic materials. The topics also include submicron technologies, nanoscale characterization, new techniques for the synthesis of nanoparticles as well as an in-depth treatment of their characterization and chemical and physical properties. Potential industrial applications of these advanced materials are also discussed.

This book provides a comprehensive overview of current achievements in biomedical applications of nanotechnology, including stem cell based regenerative medicine, medical imaging, cell targeting, drug delivery, and photothermal/photodynamic cancer therapy. New approaches in early cancer diagnosis and treatment are introduced with extensive experimental results. In particular, some novel materials have been synthesized with new properties that are most effective in cancer therapy. Some of the key issues are also addressed with these recent discoveries such as bio safety and bio degradability, that are essential in the success of nano medicine.An important aspect of this book is the introduction of nanotechnology to the medical communities that are searching for new treatments of cancer, therefore breaking barriers between the physical and medical sciences so that more MDs will be able to appreciate the new discoveries and establishments in medical diagnoses and therapies capable of tackling major clinical issues.

This book intends to provide an up-to-date information in the field of nanobiomedicine. The focus of the book is on the basic concepts and recent developments in the field of nanotechnology. This book covers a broad spectrum of nanomaterials processing, structural characteristics, and related properties and will include bio-probes, medical imaging, drug delivery, and tumor diagnosis. Critical issues are addressed in a straightforward manner so those with no technical background and university students can benefit from the information. Furthermore, many novel concepts in nanomaterials are explained in light of current theories. An important aspect of the book lies on its wide coverage in practical biomedical applications. Not only are the cutting-edge technologies in modern medicine introduced, but also unique materials applications in many clinical areas.

Recent advances in the processing of microstructured and nanostructured materials are finding application in medical diagnosis and treatment. For example, novel building blocks for bottom-up assembly of biomaterials are being designed that will simplify development of nanostructured materials. In addition, functional biomaterials are being developed that exhibit unique interactions with proteins, nucleic acids, and other biological structures. This book brings together a diverse group of materials researchers, medical device manufacturers and clinicians to discuss the use of novel techniques for processing metals, ceramics, polymers, natural materials and composite materials used in diagnosis and treatment of medical conditions. Topics include: processing of biomimetic materials; materials for bio-imaging; functional biomaterials; nanoparticles for medical diagnosis and treatment; novel materials and devices for drug delivery and biosensing; scaffolds for tissue engineering; self-assembled biomaterials; and surface modification of biomaterials.

Up-to-date introduction to the field with the focus on the critical areas of novel thin films such as sol gel synthesis of membrane, ferroelectric thin films and devices, functional nanostructured thin films, micromechanical analysis of fiber-reinforced composites, and novel applications. An important aspect of the book lies in its wide coverage of practical applications.

The current interest in developing novel materials has motivated an increasing need for biological and medical studies in a variety of dinical applications. Indeed, it is dear that to achieve the requisite mechanical, chemical and biomedical properties, especially for new bioactive materials, it is necessary to develop novel synthesis routes. The tremendous success of materials science in developing new biomaterials and fostering technological innovation arises from its focus on interdisciplinary research and collaboration between materials and medical sciences. Materials scientists seek to relate one natural phenomenon to the basic structures of the materials and to recognize the causes and effects of the phenomena. In this way, they have developed explanations for the changing of the properties, the reactions of the materials to the environment, the interface behaviors between the artificial materials and human tissue, the time effects on the materials, and many other natural occurrences. By the same means, medical scientists have also studied the biological and medical effects of these materials, and generated the knowledge needed to produce useful medical devices. The concept of biomaterials is one of the most important ideas ever generated by the application of materials science to the medical field. In traditional materials research, interest focuses primarilyon the synthesis , structure, and mechanical properties of materials commonly used for structural purposes in industry, for instance in mechanical parts of machinery.

This book focuses on the investigation of the basic properties of magnetic nanostructures, and the fundamental physics of novel nanostructures for submicron devices. It provides a broad overview of the latest developments in this emerging and fascinating field of nano-sized materials, with emphasis on the practical understanding and operation of devices using or based on nanostructured magnetic materials. The topics also include submicron technologies, nanoscale characterization, new techniques for the synthesis of nanoparticles as well as an in-depth treatment of their characterization and chemical and physical properties. Potential industrial applications of these advanced materials are also discussed.

This book explores the fascinating field of high-temperature superconductivity. Basic concepts including experimental techniques and theoretical issues are discussed in a clear, systematic manner. In addition, the most recent research results in the measurements, materials synthesis and processing, and characterization of physical properties of high-temperature superconductors are presented. Researchers and students alike can use this book as a comprehensive introduction not only to superconductivity but also to materials-related research in electromagnetic ceramics.

"Special features of the book"

presents recent developments in vortex-state properties, defects characterization, and phase equilibrium

introduces basic concepts for experimental techniques at low temperatures and high magnetic fields

provides a valuable reference for materials-related research

discusses potential industrial applications of high-temperature superconductivity

includes novel processing technologies for thin film and bulk materials

suggests areas of research and specific problems whose solution can make high-Tc superconductors a practical reality"