Reflecting the breadth of the field from research to manufacturing, Nanoscience and Nanoengineering: Advances and Applications delivers an in-depth survey of emerging, high-impact nanotechnologies. Written by a multidisciplinary team of scientists and engineers and edited by prestigious faculty of the Joint School of Nanoscience and Nanoengineering, this book focuses on important breakthroughs in nanoelectronics, nanobiology, nanomedicine, nanomodeling, nanolithography, nanofabrication, and nanosafety. This authoritative text: Addresses concerns regarding the use of nanomaterials Discusses the advantages of nanocomposites versus conventional materials Explores self-assembly and its potential for nanomanufacturing applications Covers compound semiconductors and their applications in communications Considers display technology and infrared optics in relation to nanoelectronics Explains how computational nanotechnology is critical to the design of process materials and nanobiotechnologies Describes the design and fabrication of nanoelectromechanical systems (NEMS) and their applications in nanomedicine By seamlessly integrating interdisciplinary foundational science with state-of-the-art engineering tools, Nanoscience and Nanoengineering: Advances and Applications offers a holistic approach to understanding the mechanisms underpinning the nanotechnology-based products we enjoy today, as well as those that will change our society in the near future.

Reflecting the breadth of the field from research to manufacturing, Nanoscience and Nanoengineering: Advances and Applications delivers an in-depth survey of emerging, high-impact nanotechnologies. Written by a multidisciplinary team of scientists and engineers and edited by prestigious faculty of the Joint School of Nanoscience and Nanoengineering, this book focuses on important breakthroughs in nanoelectronics, nanobiology, nanomedicine, nanomodeling, nanolithography, nanofabrication, and nanosafety. This authoritative text: Addresses concerns regarding the use of nanomaterials Discusses the advantages of nanocomposites versus conventional materials Explores self-assembly and its potential for nanomanufacturing applications Covers compound semiconductors and their applications in communications Considers display technology and infrared optics in relation to nanoelectronics Explains how computational nanotechnology is critical to the design of process materials and nanobiotechnologies Describes the design and fabrication of nanoelectromechanical systems (NEMS) and their applications in nanomedicine By seamlessly integrating interdisciplinary foundational science with state-of-the-art engineering tools, Nanoscience and Nanoengineering: Advances and Applications offers a holistic approach to understanding the mechanisms underpinning the nanotechnology-based products we enjoy today, as well as those that will change our society in the near future.

In chapters contributed by 24 university & government laboratories, Nanoengineering of Structural, Functional, and Smart Materials combines wide-ranging research aimed at the development of multifunctional materials that are strong, lightweight, and versatile. This book explores promising and diverse approaches to the design of nanoscale materials and presents concepts that integrate mechanical, electrical, electrochemical, polarization, optical, thermal, and biomimetic functions with nanoscale materials to support the development of polymer composites, thin films, fibers, pultruded materials, and smart materials having a superior combination of properties. Interrelating the many different aspects of nanoscience vital to developing new material systems, this book is organized into three parts that cover the major areas of focus: synthesis, manufacturing techniques, and modeling. The book defines functional materials and discusses techniques designed to improve material properties, durability, multifunctionality, and adaptability. It also examines sensors and actuators fabricated from nanostructured microdevices for structural health and performance monitoring. Shifting its focus to nanomechanics and the modeling of nanoscale particles, the book discusses vibration properties, thin films, and pulse laser deposition, low cost manufacturing of ceramic composites, hybrid nanocomposites, and various types of nanotubes. The book combines atomistic modeling with molecular dynamics simulations to clarify design considerations and discusses coupling between atomistic models and classical continuum mechanics models. The authors also advocate the current and potential development of commercial applications, such as nanocoatings to create "artificial skin" and functionalized nanotubes used to enhance the properties of composite materials. Nanoengineering of Structural, Functional, and Smart Materials provides an overview of current trends and cutti

In chapters contributed by 24 university & government laboratories, Nanoengineering of Structural, Functional, and Smart Materials combines wide-ranging research aimed at the development of multifunctional materials that are strong, lightweight, and versatile. This book explores promising and diverse approaches to the design of nanoscale materials and presents concepts that integrate mechanical, electrical, electrochemical, polarization, optical, thermal, and biomimetic functions with nanoscale materials to support the development of polymer composites, thin films, fibers, pultruded materials, and smart materials having a superior combination of properties. Interrelating the many different aspects of nanoscience vital to developing new material systems, this book is organized into three parts that cover the major areas of focus: synthesis, manufacturing techniques, and modeling. The book defines functional materials and discusses techniques designed to improve material properties, durability, multifunctionality, and adaptability. It also examines sensors and actuators fabricated from nanostructured microdevices for structural health and performance monitoring. Shifting its focus to nanomechanics and the modeling of nanoscale particles, the book discusses vibration properties, thin films, and pulse laser deposition, low cost manufacturing of ceramic composites, hybrid nanocomposites, and various types of nanotubes. The book combines atomistic modeling with molecular dynamics simulations to clarify design considerations and discusses coupling between atomistic models and classical continuum mechanics models. The authors also advocate the current and potential development of commercial applications, such as nanocoatings to create "artificial skin" and functionalized nanotubes used to enhance the properties of composite materials. Nanoengineering of Structural, Functional, and Smart Materials provides an overview of current trends and cutti