This book covers how the understanding, as well as controllability, of the quantum electronic properties of carbon structures can be improved through a combined study of structural geometry, electronic properties, and dynamics of resonating valence bonds. It elaborates varied properties such as growth mechanism, exotic transport properties, namely unusual geometry of microstructures mixed with electron distribution and spin properties in carbon. Transport mechanisms and new applications including hybrid quantum technology based on the superconducting diamond and diamond nitrogen-vacancy (NV) centers are discussed. Features: • Includes the theoretical and experimental aspects of carbon physics, various carbon nanostructures, and simulations. • Covers growth of carbon superstructures and various applications of their tunable electronic properties. • Discusses how nanocarbon systems can be used in emerging technologies, including spintronic and quantum computing. • Focuses on spin-related features and spin transport including the Kondo effect, spin-charge separation, spin-phonon coupling, anomalous Hall effect, and Luttinger liquid features. • Explores carbon superstructure growth and their tunable electronic properties. This book is aimed at students, researchers in physics, chemistry, engineering, materials science, electronics, and quantum technology.
This book covers how the understanding, as well as controllability, of the quantum electronic properties of carbon structures can be improved through a combined study of structural geometry, electronic properties, and dynamics of resonating valence bonds. It elaborates varied properties such as growth mechanism, exotic transport properties, namely unusual geometry of microstructures mixed with electron distribution and spin properties in carbon. Transport mechanisms and new applications including hybrid quantum technology based on the superconducting diamond and diamond nitrogen-vacancy (NV) centers are discussed. Features: • Includes the theoretical and experimental aspects of carbon physics, various carbon nanostructures, and simulations. • Covers growth of carbon superstructures and various applications of their tunable electronic properties. • Discusses how nanocarbon systems can be used in emerging technologies, including spintronic and quantum computing. • Focuses on spin-related features and spin transport including the Kondo effect, spin-charge separation, spin-phonon coupling, anomalous Hall effect, and Luttinger liquid features. • Explores carbon superstructure growth and their tunable electronic properties. This book is aimed at students, researchers in physics, chemistry, engineering, materials science, electronics, and quantum technology.
This book reconceptualizes the ancient philosophy of 'dualism' and a 'trinity' applied to classical and quantum nonequilibrium phenomena. In addition to classical mechanics and electrodynamics, a remarkable connection of this philosophy with quantum mechanics is established, which can be useful for quantum computing and the development of quantum artificial intelligence. Packed with the recent theoretical models, quantum simulations of black holes, and experimental observations of quantum phase transitions, this book brings a holistic approach that can be useful to refine the concept of the 'Creation', i.e., the evolution of the Universe from the condensed state of matter, and explain the artificial vision. The approch is: Unique: Connects ancient philosophy, classical and quantum mechanics, materials, and the latest quantum technologies. Novelty: High level of scientific interpretation of ancient philosophy, creation, interactions, and disorder. Multidisciplinary: Guides students to learn quantum simulations and develop philosophical ideas. The book contains over ten years of in-depth research by the author on the ancient eastern (Indian) philosophy and the latest scientific research in condensed matter and quantum technology. This book will simplify the picture of ancient eastern philosophy, which can be read by the general audience, particularly undergraduate/postgraduate students interested in quantum information science without any mathematical treatment. However, some parts of the book will be ideal for senior academicians and professional researchers in both worlds.
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