Nanoscience and Nanoengineering Advances and Applications

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.

The Mechanical and Biological Paradigms. NEMS: Processes and Devices. A Study of Ga Assisted Growth of GaAs/GaAsSb Axial Nanowires by Molecular Beam Epitaxy. Applications of Micro/Nanotechnology in Design and Control of Neural Interfaces. Characterization of Biological and Condensed Matter at the Nanoscale. Biological Nanostructures: Formation, Function, and Potential Applications. Current Nanodelivery Systems for Imaging and Therapeutics. Nanodevices and Systems for Clinical Diagnostics. Fullerenes and Their Potential in Nanomedicine. Modeling at Nanoscale: Material Chemistry Level Modeling in Processing and Mechanics of Engineered Materials. Computational Modeling of Bio-Nano Interfaces. Multiscale Glass Fiber Reinforced Composite Developed from Epoxy Resin Containing Electrospun Glass Nanofibers. Templated Self-Assembly for Nanolithography and Nanofabrication: Overview and Selected Examples. Understanding Toxicity of Engineered Nanomaterials. The Safety of Nanomaterials: What We Know and What We Need to Know.

Dr. Ajit D. Kelkar is professor and chair of the Nanoengineering Department at the Joint School of Nanoscience and Nanoengineering. He also serves as associate director for the Center for Advanced Materials and Smart Structures at North Carolina A&T State University and is a member of NIA, ASME, SAMPE, AIAA, ASM, and ASEE. Currently he is involved in the development of nanoengineered multifunctional materials using carbon nanotubes (CNTs), boron nitride nanotubes (BNNTs), electrospun nanofiber materials, and alumina nanoparticles. He also is working on atomistic modeling of polymers embedded with CNTs, BNNTs, and alumina nanoparticles; is involved in high-velocity impact modeling of ceramic matrix composites and polymeric matrix composites embedded with electrospun nanofibers; has published over 200 papers in these areas; and has edited a book on nanoengineered materials.

Dr. Daniel Herr is professor and chair of the Nanoscience Department at the Joint School of Nanoscience and Nanoengineering. Previously he served as director of nanomanufacturing sciences for Semiconductor Research Corporation (SRC). His research is focused on designed nanoengineered materials, advanced patterning and directed self-assembly, nanomanufacturing, formulation, process qualification and optimization, sustainable technologies, and advanced device design. Recently he was elected SPIE fellow and the AAAS Industrial Science and Technology section’s member-at-large. He is the inventor of several foundational patents and disclosures on defect tolerant patterning, controlled nanotube synthesis and placement, deterministic semiconductor doping, and ultimate CMOS devices. He serves as senior editor for IEEE Transactions in Nanotechnology and coordinating editor for the Journal of Nanoparticle Research. In 2005, he received the National Medal of Technology from SRC.

Dr. James G. Ryan is the founding dean of the Joint School of Nanoscience and