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Active-site is the region at the central atom’s position where functional activated reactions occur in many materials. Hence, it is important for the present study of material sciences to take into consideration this information of atomic structures in the reaction center of the localized impurities and catalyst and phase boundary and the photosynthetic reaction centers. However, it is very difficult to determine a three-dimensional atomic structure directly in the center positions of many functional materials.This book is written for readers to gain the basic knowledge of this “active-site”. It will benefit those who want to know the function and structure of the inorganic, organic and biological materials.
Experimental Mechanics of Composite, Hybrid, and Multifunctional Materials, Volume 7 of the Proceedings of the 2015SEM Annual Conference& Exposition on Experimental and Applied Mechanics, the seventh volume of nine from the Conference, brings together contributions to this important area of research and engineering. The collection presents early findings and case studies on a wide range of areas, including: Multifunctional Materials Hybrid Materials Novel Composites Nano- and Particle-Reinforced Composites Additive Manufacturing of Composites Digital Imaging of Composites Damage Detection Non-Destructive Evaluation Fatigue and Fracture of Composites Manufacturing and Joining of Composites Advanced Composites Applications
Fabricate 2024: Creating Resourceful Futures is the fifth volume in the series of Fabricate publications. The first conference – ‘Making Digital Architecture’ – explored the ways in which technology, design and industry are shaping the world around us. Since then, we have become finely attuned to the negative impacts of this shaping. The 2024 conference, hosted in Copenhagen, sets focus on the pressing need to develop new models for architectural production that rethink how resource is deployed, its intensity, its socio-ecological origins and sensitivity to environment. This book features the work of designers, engineers and makers operating within the built environment. It documents disruptive approaches that reconsider how fabrication can be leveraged to address our collective and entangled challenges of resource scarcity, climate emergency and burgeoning demand. Exploring case studies of completed buildings and works-in-progress, together with interviews with leading thinkers, this edition of Fabricate offers a plurality of tangible models for design and production that set a creative and responsible course towards resourceful futures.
The problem of solving complex engineering problems has always been a major topic in all industrial fields, such as aerospace, civil and mechanical engineering. The use of numerical methods has increased exponentially in the last few years, due to modern computers in the field of structural mechanics. Moreover, a wide range of numerical methods have been presented in the literature for solving such problems. Structural mechanics problems are dealt with using partial differential systems of equations that might be solved by following the two main classes of methods: Domain-decomposition methods or the so-called finite element methods and mesh-free methods where no decomposition is carried out. Both methodologies discretize a partial differential system into a set of algebraic equations that can be easily solved by computer implementation. The aim of the present Special Issue is to present a collection of recent works on these themes and a comparison of the novel advancements of both worlds in structural mechanics applications.
The volume focuses on theoretical and computational approaches and involves areas such as simulation-based engineering and science, integrated computational materials engineering, mechanics, material science, manufacturing processes, and other specialized areas. Most importantly, the state-of-the-art progress in developing predictive theoretical, computational and experimental approaches for additive manufacturing is summarized.
Since a formulated concept of functionally graded materials (FGMs) was proposed in 1984 as a means of preparing thermal barrier materials, a coordinated research has been developed since 1986. The 125 papers presented here present state of the art research results and developments on FGM from the past decade.A wide spectra of topics are covered including design and modeling, fracture analysis, powder metallurgical processes, deposition and spray processes, reaction forming processes, novel processes, material evaluation for structural applications, organic and intelligent materials. Three reviews associated with national research programs on FGMs promoted in Japan and Germany, and the historical perspective of FGM research in Europe are presented as well.The resulting work is recommended to researchers, engineers and graduate school students in the fields of materials science and engineering, mechanical and medical engineering.
Nanomembranes Provides a thorough overview of the field of nanomembranes, covering materials science, fabrication processes, properties, and applications In recent years, the unique nature of the nanomembrane has led to new technology and applications in areas including flexible electronics, photonics, robotics, biology, microelectromechanical systems, and lab-on-a-chip (LOC) devices. Highly suitable for assembling three-dimensional structures, the nanomembrane can be integrated into devices and systems using conventional thin film technology. Nanomembranes: Materials, Properties, and Applications is an up-to-date review of recent advances in the rapidly expanding area within nanoscience and technology. Edited by leading researchers, the book covers the fabrications, properties, applications, design concepts, and challenges of nanomembranes and other nano-scale assembled structures. In-depth chapters address topics including three- and four-dimensional origami, nanomembrane-based transient electronics, development of inorganic flexible electronics, magnetic nanomembranes, bio-applications of three-dimensional scaffolds, nanomembrane-based micro and nanorobots, passive electronic components based on self-rolled-up nanomembranes, and more. Covers nanomembranes as well as nanostructures made from semiconductor, metal, insulator, polymer, and composite materials Provides broad overview of two-dimensional materials and assembled structures including origami and kirigami structures Explores applications of nanomembrane such as batteries, supercapacitors, robotics, electronics, and cell scaffolding Discusses nanomembranes made from polymeric materials, mechanical forces during deformation, and assembly of nanomembranes, Addresses monolayer two-dimensional materials such as graphene and transition metal dichalcogenides Nanomembranes: Materials, Properties, and Applications is an invaluable resource for material scientists, engineers, physicists, and chemists in academia and industry, and an excellent text for graduate students and researchers across disciplines with interest in the rapidly growing field.
This book constitutes the refereed proceedings of the 16th International Conference on Computer-Aided Architectural Design Futures, CAAD Futures 2015, held in São Paulo, Brazil, in July 2015. The 33 revised full papers presented were carefully reviewed and selected from 200 submissions. The papers are organized in topical sections on modeling, analyzing and simulating the city; sustainability and performance of the built space; automated and parametric design; building information modelling (BIM); fabrication and materiality; shape studies.
Scaffold bone replacements are a safe and effective way to cure bone abnormalities, and porous scaffolds can be manufactured using additive manufacturing technology. When scaffolds are implanted in a damaged location, they quickly connect to the host tissue and integrate, stimulating bone production and development. The qualities of porous titanium must be matched to the properties of human bones (i.e., age, sex, and hormones). Using subtractive manufacturing, it is extremely difficult to create the complicated porous structure necessary for the desired characteristic. The Handbook of Research on Advanced Functional Materials for Orthopedic Applications highlights current research pertinent to the orthopedic applications of additive-produced scaffolds in order to consider the latest breakthroughs in the synthesis and multifunctional applications of scaffolds. Covering key topics such as tissue, additive manufacturing, and biomaterial, this major reference work is ideal for industry professionals, engineers, researchers, academicians, practitioners, scholars, instructors, and students.