Complex Phenomena In Nanoscale Systems

Nanoscale physics has become one of the rapidly developing areas of contemporary physics because of its direct relevance to newly emerging area, nanotechnologies. Nanoscale devices and quantum functional materials are usually constructed based on the results of fundamental studies on nanoscale physics. Therefore studying physical phenomena in nanosized systems is of importance for progressive development of nanotechnologies. In this context study of complex phenomena in such systems and using them for controlling purposes is of great practical importance. Namely, such studies are brought together in this book, which contains 27 papers on various aspects of nanoscale physics and nonlinear dynamics.

This book presents the structure formation and dynamics of animate and inanimate matter on the nanometre scale. This is a new interdisciplinary field known as Meso-Bio-Nano (MBN) science that lies at the intersection of physics, chemistry, biology and material science. Special attention in the book is devoted to investigations of the structure, properties and dynamics of complex MBN systems by means of photonic, electronic, heavy particle and atomic collisions. This includes problems of fusion and fission, fragmentation, surfaces and interfaces, reactivity, nanoscale phase and morphological transitions, irradiation-driven transformations of complex molecular systems, collective electron excitations, radiation damage and biodamage, channeling phenomena and many more. Emphasis in the book is placed on the theoretical and computational physics research advances in these areas and related state-of-the-art experiments. Particular attention in the book is devoted to the utilization of advanced computational techniques and high-performance computing in studies of the dynamics of systems.

This book collects selected lectures from the Third Workshop of the Croucher Advanced Study Institute on Nano Science and Technology, and showcases contributions from world-renowned researchers. The book presents in-depth articles on the latest developments in nanomaterials and nanotechnology, and provides a cross-disciplinary perspective covering physics and biophysics, chemistry, materials science, and engineering.

The main intention of the editors of the book is the demonstration of the intrinsic correlation and mutual influence of three important components of nanoscience: new phenomena – nanomaterials – nanodevices. This is the organizing concept of the book. To discover new phenomena it is necessary to develop novel nanotechnological processes for fabrication of nanomaterials. Nanostructures and new phenomena serve as the base for the development of novel nanoelectronic devices and systems. The articles selected for the book illustrate this interrelation.

This book explains the application of recent advances in computational intelligence – algorithms, design methodologies, and synthesis techniques – to the design of integrated circuits and systems. It highlights new biasing and sizing approaches and optimization techniques and their application to the design of high-performance digital, VLSI, radio-frequency, and mixed-signal circuits and systems. This second of two related volumes addresses digital and network designs and applications, with 12 chapters grouped into parts on digital circuit design, network optimization, and applications. It will be of interest to practitioners and researchers in computer science and electronics engineering engaged with the design of electronic circuits.

To realize the full potential of micro- and nanoscale devices in system building, it is critical to develop systems engineering methodologies that successfully integrate stand-alone, small-scale technologies that can effectively interface with the macro world. So how do we accomplish this?Systems Engineering for Microscale and Nanoscale Technologie

Nanotechnology is a multidisciplinary field that involves the manipulation and control of matter at the nanoscale, typically ranging from 1 to 100 nanometers. At this scale, the properties of materials can significantly differ from their bulk counterparts, leading to unique and enhanced functionalities. The physics behind nanotechnology encompasses various principles and phenomena that govern the behavior of matter at the nanoscale. In this book, we can see how these principles help explain phenomena related to heat transfer, phase transitions, and fluctuations at the nanoscale. Understanding these principles is crucial for designing and optimizing nanoscale devices and systems. One of the fundamental concepts in nanotechnology is quantum mechanics. Quantum mechanics describes the behavior of particles at the atomic and subatomic levels. It provides a framework for understanding phenomena such as wave-particle duality, quantization of energy levels, and tunneling. In nanotechnology, quantum mechanics plays a crucial role in explaining the electronic properties of nanomaterials. Mathematical modelling plays a vital role in understanding and predicting the behavior of nanoscale systems. It provides a quantitative framework for describing complex phenomena and optimizing device performance. Mathematical models in nanotechnology often involve differential equations, statistical methods, and computational simulations.It is crucial for understanding the mechanical properties of nanomaterials. Models based on continuum mechanics, such as elasticity theory and plasticity theory, can predict the behavior of nanomaterials under different loading conditions. These models help in designing materials with desired mechanical properties and optimizing their performance. Mathematical models also aid in the design and optimization of nanoscale devices such as sensors, transistors, and solar cells. By simulating device behavior using mathematical models, researchers can optimize device parameters to achieve desired performance characteristics.