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This Handbook covers the fundamental aspects, experimental setup, synthesis, properties, and characterization of different nanocelluloses. It also explores the technology challenges of nanocelluloses and the emerging applications and the global markets of nanocelluloses-based systems. In particular, this book:· Covers the history of nanocelluloses, types and classifications, fabrication techniques, critical processing parameters, physical and chemical properties, surface functionalization, and other treatments to allow practical applications. · Covers all recent aspects of nanocelluloses technologies, from experimental set-up to industrial applications. · Includes new physical, chemical and biological techniques for nanocelluloses fabrication, in-depth treatment of their surface functionalization, and characterization. · Discusses the unique properties of nanocelluloses that can be obtained by modifying their diameter, morphology, composition and dispersion in other materials.· Discusses the properties and morphology of several kinds of dispersion in polymeric materials, such as micro/nanofiberlated cellulose, cellulose nanofibers, cellulose nanocrystals, amorphous cellulose nanoparticles, and hybrid cellulose nanomaterials. · Presents the different techniques for dispersion, and self-assembly of polymeric materials, critical parameters of synthesis, modelling and simulation, and characterization methods. · Highlights a wide range of emerging applications of nanocelluloses, e.g. drug delivery, tissue engineering, medical implants, medical diagnostics and therapy, biosensors, catalysis, energy harvesting, energy storage, water/waste treatment, papermaking, textiles, construction industry, automotive, aerospace and many more. · Provides an outlook on the opportunities and challenges for the fabrication and manufacturing of nanocelluloses in industry.· Provides an in-depth look at the nature of nanocelluloses in terms of their applicability for industrial uses.· Provides in-depth insight and review on most recent types of nanocelluloses-based systems of unique structures and compositions. · Highlights the challenges and interdisciplinary perspective of nanocelluloses-based systems in science, biology, engineering, medicine, and technology, incorporating both fundamentals and applications.- Demonstrates how cutting-edge developments in nanofibers translate into real-world innovations in a range of industry sectors. This Handbook isa valuable reference for materials scientists, biologists, physicians, chemical, biomedical, manufacturing and mechanical engineers working in R&D industry and academia, who want to learn more about how nanocelluloses-based systems are commercially applied.

Diverse Quasiparticle Properties of Emerging Materials: First-Principles Simulations thoroughly explores the rich and unique quasiparticle properties of emergent materials through a VASP-based theoretical framework. Evaluations and analyses are conducted on the crystal symmetries, electronic energy spectra/wave functions, spatial charge densities, van Hove singularities, magnetic moments, spin configurations, optical absorption structures with/without excitonic effects, quantum transports, and atomic coherent oscillations.Key FeaturesIllustrates various quasiparticle phenomena, mainly covering orbital hybridizations and spin-up/spin-down configurationsMainly focuses on electrons and holes, in which their methods and techniques could be generalized to other quasiparticles, such as phonons and photonsConsiders such emerging materials as zigzag nanotubes, nanoribbons, germanene, plumbene, bismuth chalcogenide insulatorsIncludes a section on applications of these materialsThis book is aimed at professionals and researchers in materials science, physics, and physical chemistry, as well as upper-level students in these fields.

There are more than 20 million chemicals in the literature, with new materials being synthesized each week. Most of these molecules are stable, and the 3-dimensional arrangement of the atoms in the molecules, in the various solids may be determined by routine x-ray crystallography. When this is done, it is found that this vast range of molecules, with varying sizes and shapes can be accommodated by only a handful of solid structures. This limited number of architectures for the packing of molecules of all shapes and sizes, to maximize attractive intermolecular forces and minimizing repulsive intermolecular forces, allows us to develop simple models of what holds the molecules together in the solid. In this volume we look at the origin of the molecular architecture of crystals; a topic that is becoming increasingly important and is often termed, crystal engineering. Such studies are a means of predicting crystal structures, and of designing crystals with particular properties by manipulating the structure and interaction of large molecules. That is, creating new crystal architectures with desired physical characteristics in which the molecules pack together in particular architectures; a subject of particular interest to the pharmaceutical industry.

This book will introduce advanced concepts and topics of solid-state theory. To this end we need a tool box that enables us to treat electron-electron interactions, and possibly also electron-phonon or phonon-phonon interactions in some well-defined, appro

Ultra-BriefThis book provides the most fundamental and essential techniques to simulate complex systems, from the dynamics of molecules to the spreading of diseases, from optimization using ant colonies to the simulation of the Game of Life.

*Shortlisted for the 2019 Royal Society Insight Investment Science Book Prize* One of the most fascinating scientific detective stories of the last fifty years, an exciting quest for a new form of matter. “A riveting tale of derring-do” (Nature), this book reads like James Gleick’s Chaos combined with an Indiana Jones adventure.When leading Princeton physicist Paul Steinhardt began working in the 1980s, scientists thought they knew all the conceivable forms of matter. The Second Kind of Impossible is the story of Steinhardt’s thirty-five-year-long quest to challenge conventional wisdom. It begins with a curious geometric pattern that inspires two theoretical physicists to propose a radically new type of matter—one that raises the possibility of new materials with never before seen properties, but that violates laws set in stone for centuries. Steinhardt dubs this new form of matter “quasicrystal.” The rest of the scientific community calls it simply impossible. The Second Kind of Impossible captures Steinhardt’s scientific odyssey as it unfolds over decades, first to prove viability, and then to pursue his wildest conjecture—that nature made quasicrystals long before humans discovered them. Along the way, his team encounters clandestine collectors, corrupt scientists, secret diaries, international smugglers, and KGB agents. Their quest culminates in a daring expedition to a distant corner of the Earth, in pursuit of tiny fragments of a meteorite forged at the birth of the solar system. Steinhardt’s discoveries chart a new direction in science. They not only change our ideas about patterns and matter, but also reveal new truths about the processes that shaped our solar system. The underlying science is important, simple, and beautiful—and Steinhardt’s firsthand account is “packed with discovery, disappointment, exhilaration, and persistence...This book is a front-row seat to history as it is made” (Nature).