The book begins by detailing the steps required to turn an idea into a marketable product. The editors give examples of previously successful products and relate to their own experiences in development. Next, the text focuses on the importance of entrepreneurship and the required steps to finance and develop a marketing strategy. It contains various definitions of nanotechnology and how each relates to roadmap and production issues. Three detailed case studies from the leading MNT development and manufacturing companies describe how each venture started and progressed to become a market leader. These studies offer valuable insight into overcoming the challenges related to achieving financial backing and specifying the right product for development.

The book begins with a historical perspective of PSP and introduces photonic components essential for photonic processing systems, such as optical amplification devices, optical fibers, and optical modulators. The author demonstrates the representation of photonic circuits via a signal flow graph technique adapted for photonic domain. He describes photonic signal processors, such as differentiators and integrators, and their applications for the generation of solitons, and then covers the application of these solitons in optically amplified fiber transmission systems. The book illustrates the compensation dispersion using a photonic processor, the design of optical filters using photonic processor techniques, and the filtering of microwave signals in the optical domain.

Sensors, Nanoscience, Biomedical Engineering, and Instruments provides thorough coverage of sensors, materials and nanoscience, instruments and measurements, and biomedical systems and devices, including all of the basic information required to thoroughly understand each area. It explores the emerging fields of sensors, nanotechnologies, and biological effects. Each article includes defining terms, references, and sources of further information.

The first chapters analyze progressive approaches to controlling more precisely the structure, morphology, and surface properties of novel activated carbons. They cover methods using activating agents such as alkaline hydroxides as well as endo- and exotemplates made from zeolites, silica, and colloidal crystals. The third chapter examines techniques for characterizing carbon surface chemistry, including electrochemical, spectroscopic, and chromatographic methods. The fourth and final chapter compares the virtues of exfoliated graphite, carbonized fir fibers, carbon fiber felt, and charcoals in solving oil spill problems, a matter of increasing environmental concern.

The text surveys theory, characterization, processing, and experimental aspects of phase morphology development and design of polymer blends. It examines the adhesion of polymer–polymer interfaces in immiscible polymer blends and the different ways by which nanostructures may be generated in thermosetting polymers. The book analyzes the polymerization process and the dynamic vulcanization of multicomponent polymer blends and the crystallization behavior occurring in blends with a confined morphology. It also discusses the structure–rheology relationship in compatibilized blends, the effects of elasticity on the structure development, and the rheological response in concentrated blends.

Nanotechnology:  Legal Aspects provides thorough, yet comprehensible overview of different legal doctrines that are relevant to nanotechnology and explains how they may apply in the development, commercialization, and use of nano-products. The book is divided into three parts that correspond to the different phases in the lifecycle of nano-products: Protection, Regulation, and Liability. The in-depth coverage of these topics in a single source sets this work apart from others at the interface of law and nanoscience.

Accessible to those without specific training in either nanotechnology or law...