A compendium of novel information on molecular-scale science and the application of nanocarbon, nanosilicon and biopolymer integrated nanosystems.

During the 20th century, molecular-scale science and nanotechnology developed rapidly, leading to the construction of innovative materials - nanosystens from molecules (fullerenes), supramolecules (nanotubes, peapods, polymers, biopolymers (DNA, protein and their complexes) and semiconductor nanoparticles (nano-Si, SiOx, Si/SiGe dots, metal nanowires). This book presents exciting new developments of the early 21st century. Significant progress has been made in nanotechnology of building blocks for integrated nanosystems, single and assembled molecules, nanoparticles characterisation, and multifunctional applications of nanosystems.

The realisation and the application of novel multifunctional nanosystems in electronics, optics, biomedicine (nano-bioelectronic devices based on DNA and proteins, silicon nanocrystal memory devices, monolithically integrated silicon photonics, nanocapsules, biosensor nanosystems) are described by well known experts.

General routes to the development of innovative, multi functional nanosystems are described by experts in the field. The systems described are based on fullerenes, nanotubes, metals (Au, Ag, Pt, etc.) and semiconductors (Si, CdS, CdTe, metal oxides), nanocrystals and polymer / biopolymer assembly systems. The book also discusses the realization and characterization of the fundamental properties of nanosystems, defined by nano-size effects, as well as the application of such systems in electronics, optics, magnetoelectronics, spintronics, biomedicine, pharmaceutical biocomplexes, and biosensors.

Since their discovery, low dimensional materials have never stopped to intrigue scientists, whether they are physicists, chemists, or biochemists. Investigations of their nature and functions have always been and still are numerous and as soon as a solution is found for a given question, another one is raised. The coupling of nano-materials with photonics, i. e. nano-photonics, has produced a boiling pot of idea, problems, discovery and applications. This statement is abundantly illustrated in the present book. The interest in nano-optoelectronic materials and systems is very widespread, what gives a really international and multicultural flavour to nano-optoelectronic meetings. One of them was organized by our-self in May 2000 in Kiev as a NATO Advanced Research Workshop and EC-Spring School. The arrival of the new millennium provides an obvious transition point at which many aspects of nano-science and nano-engineering of nano photonic systems can be assessed with respect to the research progresses made in the pre ceding decades and to the challenges that lie ahead in the coming decades. This book was planed to mark this with the objective of presenting a collection of papers from experts, which provide broad perspectives on the state-of-the-art in the various disciplines of nano science and nano-engineering and on the directions for future research."

Nanoscale Science, whose birth and further growth and development has been driven by the needs of the microelectronics industry on one hand, and by the sheer human curiosity on the other hand, has given researchers an unprecedented capability to design and construct devices whose function ality is based on quantum and mesoscopic effects. A necessary step in this process has been the development of reliable fabrication techniques in the nanometer scale: two-dimensional systems, quantum wires and dots, and Coulomb blockade structures with almost ideal properties can nowadays be fabricated, and subjected to experimental studies. How does one fabricate micro/nanostructures of low dimensionality? How does one perform a nanoscale characterization of these structures? What are the fundamental properties typical to the structures? Which new physical processes in nanostructures need to be understood? What new physical processes may allow us to create new nanostructures? An improved understanding of these topics is necessary for creation of new concepts for future electronic and optoelectronic devices and for characterizing device structures based on those concepts."

Nanoscale Science, whose birth and further growth and development has been driven by the needs of the microelectronics industry on one hand, and by the sheer human curiosity on the other hand, has given researchers an unprecedented capability to design and construct devices whose function ality is based on quantum and mesoscopic effects. A necessary step in this process has been the development of reliable fabrication techniques in the nanometer scale: two-dimensional systems, quantum wires and dots, and Coulomb blockade structures with almost ideal properties can nowadays be fabricated, and subjected to experimental studies. How does one fabricate micro/nanostructures of low dimensionality? How does one perform a nanoscale characterization of these structures? What are the fundamental properties typical to the structures? Which new physical processes in nanostructures need to be understood? What new physical processes may allow us to create new nanostructures? An improved understanding of these topics is necessary for creation of new concepts for future electronic and optoelectronic devices and for characterizing device structures based on those concepts.

A compendium of novel information on molecular-scale science and the application of nanocarbon, nanosilicon and biopolymer integrated nanosystems.

During the 20th century, molecular-scale science and nanotechnology developed rapidly, leading to the construction of innovative materials - nanosystens from molecules (fullerenes), supramolecules (nanotubes, peapods, polymers, biopolymers (DNA, protein and their complexes) and semiconductor nanoparticles (nano-Si, SiOx, Si/SiGe dots, metal nanowires). This book presents exciting new developments of the early 21st century. Significant progress has been made in nanotechnology of building blocks for integrated nanosystems, single and assembled molecules, nanoparticles characterisation, and multifunctional applications of nanosystems.

The realisation and the application of novel multifunctional nanosystems in electronics, optics, biomedicine (nano-bioelectronic devices based on DNA and proteins, silicon nanocrystal memory devices, monolithically integrated silicon photonics, nanocapsules, biosensor nanosystems) are described by well known experts.

This multi-disciplinary, scientific display of cutting-edge research across the entire spectrum of nanoscience and nanotechnology of inorganic, and organic systems, as well as systems for electronics photonics, and spintronics demonstrates that researching nanocarbon, nanosilicon, biomolecular integrated nanosystems, and developing their new applications, is a complex and exiting topic that will continue to attract scientists and engineers for many years to come.

General routes to the development of innovative, multi functional nanosystems are described by experts in the field. The systems described are based on fullerenes, nanotubes, metals (Au, Ag, Pt, etc.) and semiconductors (Si, CdS, CdTe, metal oxides), nanocrystals and polymer / biopolymer assembly systems. The book also discusses the realization and characterization of the fundamental properties of nanosystems, defined by nano-size effects, as well as the application of such systems in electronics, optics, magnetoelectronics, spintronics, biomedicine, pharmaceutical biocomplexes, and biosensors.

Since their discovery, low dimensional materials have never stopped to intrigue scientists, whether they are physicists, chemists, or biochemists. Investigations of their nature and functions have always been and still are numerous and as soon as a solution is found for a given question, another one is raised. The coupling of nano-materials with photonics, i. e. nano-photonics, has produced a boiling pot of idea, problems, discovery and applications. This statement is abundantly illustrated in the present book. The interest in nano-optoelectronic materials and systems is very widespread, what gives a really international and multicultural flavour to nano-optoelectronic meetings. One of them was organized by our-self in May 2000 in Kiev as a NATO Advanced Research Workshop and EC-Spring School. The arrival of the new millennium provides an obvious transition point at which many aspects of nano-science and nano-engineering of nano photonic systems can be assessed with respect to the research progresses made in the pre ceding decades and to the challenges that lie ahead in the coming decades. This book was planed to mark this with the objective of presenting a collection of papers from experts, which provide broad perspectives on the state-of-the-art in the various disciplines of nano science and nano-engineering and on the directions for future research."