Supermaterials


Book Description

What is a supermaterial? A concise definition is by no means obvious, but a clue can be obtained from the topics discussed here.. In addition to superconductors, the reader will encounter magnetic effects of many kinds, including giant and even colossal ones, organic conductors, photoconductors, and even 400-year-old Japanese ceramics. Processing is a prominent pursuit in supermaterials research, especially but not exclusively of the superconductors. The papers on characterisation and theory break new ground, particularly in pursuit of new optoelectronic phenomena. The parade of new materials recently synthesised, often containing four or more elements, is surprising. But it is in it reporting of new applications that the book stands out: from circuits to sensors, supermaterials are making their impact on society.




Materials Science


Book Description

Explains how scientists study materials at the microscopic level and then use that knowledge to create supermaterials.




Integration of 2D Materials for Electronics Applications


Book Description

This book is a printed edition of the Special Issue "Integration of 2D Materials for Electronics Applications" that was published in Crystals




Synthesis of Biocomposite Materials


Book Description

Biomaterials have been used for artificial-organ and bioreactor materials, and have gained importance for enhancement of human welfare. This book summarizes research devoted to creating useful biofunctional materials by chemical modification of natural polymers, and forecasts future development.




Electric Refractory Materials


Book Description

An exploration of electric refractory materials, this book covers developments of blue light-emitting diodes using GaN-based nitrides for laser and high-temperature and -frequency devices. "Electric Refractory Materials" introduces growth and evaluation standards of films and bulk crystals, with consideration of band structure, surface electronic structure, and lattice vibrations. It also covers heat capacity and thermal conductivity, irradiation properties, and selective surfaces. Focusing on diamond material, the book examines its synthesis and characterization as well as its electrical, optical, and conductive properties. The book also discusses the use of silicon carbide, boron compounds, and other material used in electronic and light-emitting devices.




Innovative Superhard Materials and Sustainable Coatings for Advanced Manufacturing


Book Description

Modern industry imposes ever increasing requirements upon tools and tool materials as to the provision for performance under the conditions of high cutting speeds and dynamic loads as well as under intensive thermal and chemical interactions with workpiece materials. The industry demands a higher productivity in combination with the accuracy of geometry and dimensions of workpieces and quality of working surfaces of the machined pieces. These requirements are best met by the tool superhard materials (diamond and diamond-like cubic boron nitride). Ceramics based on silicon carbide, aluminum and boron oxides as well as on titanium, silicon and aluminum nitrides offer promise as tool materials. Tungsten-containing cemented carbides are still considered as suitable tool materials. Hi- hardness and high strength composites based on the above materials fit all the requirements imposed by machining jobs when manufacturing elements of machinery, in particular those operating under the extreme conditions of high temperatures and loads. These elements are produced of difficult-- machine high-alloy steels, nickel refractory alloys, high-tech ceramics, materials with metallic and non-metallic coatings having improved wear resistance, as well as of special polymeric and glass-ceramic materials. Materials science at high pressure deals with the use of high-pressure techniques for the development and production of unique materials whose preparation at ambient pressure is impossible (e. g. , diamond, cubic boron nitride, etc. ) or of materials with properties exceeding those of materials produced at ambient pressure (e. g. , high-temperature superconductors).




Mechanics of Magnetostrictive Materials and Structures


Book Description

Mechanics of Magnetostrictive Materials and Structures demonstrates the practical applications and uses for cutting-edge smart magnetostrictive materials. Exploring the analytical and numerical solution procedures and characteristics of these materials more generally, the book details how these materials respond to external factors. Exceptionally adjustable and adaptable, magnetostrictive materials are artifcial structures that offer distinctive physical properties. Providing clear illustrations throughout, this book includes a comprehensive guide to the theory and its applications. Comprehensively assessing the practicalities of these smart materials, it also discusses vibration and buckling under different loads, alongside dynamic behavior. Features: Presents vibration analysis of magnetostrictive materials and structures Demonstrates and analyzes the effect of implementing boundary conditions on the mechanical responses of magnetostrictive structures Examines the use of smart materials in engineering structures Aimed at students and professionals working in the field of mechanics, materials and dynamics, the book is an essential guide to this rapidly developing area.




Advanced Materials Science & Technology in China: A Roadmap to 2050


Book Description

As one of the eighteen field-specific reports comprising the comprehensive scope of the strategic general report of the Chinese Academy of Sciences, this sub-report addresses long-range planning for developing science and technology in the field of advanced materials science. They each craft a roadmap for their sphere of development to 2050. In their entirety, the general and sub-group reports analyze the evolution and laws governing the development of science and technology, describe the decisive impact of science and technology on the modernization process, predict that the world is on the eve of an impending S&T revolution, and call for China to be fully prepared for this new round of S&T advancement. Based on the detailed study of the demands on S&T innovation in China's modernization, the reports draw a framework for eight basic and strategic systems of socio-economic development with the support of science and technology, work out China's S&T roadmaps for the relevant eight basic and strategic systems in line with China's reality, further detail S&T initiatives of strategic importance to China's modernization, and provide S&T decision-makers with comprehensive consultations for the development of S&T innovation consistent with China's reality. Supported by illustrations and tables of data, the reports provide researchers, government officials and entrepreneurs with guidance concerning research directions, the planning process, and investment. Founded in 1949, the Chinese Academy of Sciences is the nation's highest academic institution in natural sciences. Its major responsibilities are to conduct research in basic and technological sciences, to undertake nationwide integrated surveys on natural resources and ecological environment, to provide the country with scientific data and consultations for government's decision-making, to undertake government-assigned projects with regard to key S&T problems in the process of socio-economic development, to initiate personnel training, and to promote China's high-tech enterprises through its active engagement in these areas.







Introduction To Materials Science


Book Description

An extensive range of material categories, including metals, polymers, ceramics, composites, semiconductors, biomaterials, and nanomaterials, can be distinguished and defined as distinct fields. Materials science is an expansive discipline that can be classified as an interdisciplinary field. It encompasses investigations into the composition and characteristics of any substance, the development of novel material varieties, and the adjustment of a substance's properties to suit the requirements of a particular application. Characterization is the foundation of materials science; it entails establishing a relationship between the configuration of atoms and phases within a material and its relative performance and desired properties in a given application. In the process of material selection for a specific application, the physical properties of the material typically hold significant influence. This involves, among other things, the composition and structure of the material, analysis of fracture and stress, conductivity, optical, and thermal properties. Methods of processing, manufacturing, modelling, and design are also incorporated. Crystallography, microscopy, lithography, mineralogy, photonics, and powder diffraction are just few of the peripheral fields that are involved in the research that is conducted in the discipline of materials science.