The progress of civilization can be, in part, attributed to their ability to employ metallurgy. This book is an introduction to multiple facets of physical metallurgy, materials science, and engineering. As all metals are crystalline in structure, it focuses attention on these structures and how the formation of these crystals are responsible for certain aspects of the material's chemical and physical behaviour. Concepts in Physical Metallurgy also discusses the mechanical properties of metals, the theory of alloys, and physical metallurgy of ferrous and non-ferrous alloys.

Steel has, over centuries, played a crucial role in shaping our material, and in particular, urban landscapes. This books undertakes a cultural and ecological history of the material, examining the relationship between steel and design at a micro and macro level - in terms of both what it has been used to design and how it has functioned as a 'world-making force', necessary to the development of technologies and ideas. The research for the book is informed by diverse fields of literature including industry journals, contemporary accounts and technical literature - all framed by rich, early accounts of iron and steel making from the middle ages to the opening of the industrial age, and most notably, the crucial works of Vannoccio Biringuccio, Georgius Agricola, Andrew Ure and Harry Scrivenor. In contrast, trans-cultural accounts of the history of metallurgy from eminent sinologists and cultural historians like Joseph Neeham and G.E.R. Lloyd are used. Readings on the pre-history and history of science, as well as histories and philosophies technology from scholars such as Siegfried Giedion, Merritt Roe Smith, L.T.C Rolt, Robert B. Gordon inform the analysis. Social and economic history from historians such as Eric Hobsbawn, William T. Hogan and David Brody are consulted; labour process theory is also examined, particularly the influential writings of F.W. Taylor in the late 19th and early 20th centuries and his contemporary critics, like David Nobel and Harry Braverman. Many other disciples also inform the account: histories of urban design and architecture, transport and military history, environmental history and geography.

Wire drawing is a metalworking process used to reduce the diameter of a wire by pulling the wire through a single, or series of, drawing die(s). The engineering applications of wire drawing are broad and far-reaching, including electrical wiring, cables, tension-loaded structural components, springs, paper clips and spokes for wheels.

This all-new, classical text is the first to explain the complex theory and sophisticated engineering concepts with relation to wire drawing in an accessible and universal way for practicing engineers.

Designed to facilitate the entry and training of new engineers and upgrade the professional practice of those already in the field in the face of increased product demands and tightening specifications, this essential resource by industry expert Roger Wright provides: A technical overview and introduction of engineering concepts related to wire drawing, suitable for beginners and practiced engineers looking to brush up on the theory behind the processAn interface with basic engineering education so as to provide an accessible introduction for engineers new to the fieldReal-world worked examples, problems and protocols based on true life engineering scenarios and challengesUnique coverage of the author's own pass design and risk prediction calculations, developed through decades of research and wire industry consulting

Whilst most competing titles are less practical in their approach and focus on either ferrous, non-ferrous or electrical, our book takes a universal approach more suited to the practicing engineer who needs knowledge of wire drawing across the board. Ideal for use as a complete insight into the process from start to finish or a dip-in resource for practical problem-solving, this versatile work-a-day guide, training tool and desk reference will help readers train their staff and adapt and improve processes at minimal cost for maximum performance.
Provides a unique universal approach, covering ferrous and non-ferrous metalsAuthored by an internationally-recognized specialist in wire drawing with extensive academic and industry experienceReal-world worked examples, problems and protocols based on true life engineering scenarios and challenges allow engineers to easily apply the theory to their workplace to improve processes, productivity and efficiencyCompact, concise and practical in comparison to the large, competing handbook tomes that are overwhelming for beginners and impractical for day-to-day work useIdeal for use as a complete insight into the process from start to finish or as a dip-in resource for practical problem-solving, analysis and trouble-shooting

This book presents the physical concepts and tools to characterize and describe the formation of metastable solids from undercooled melts. Its aim is to facilitate understanding of the development of the science and technology of solidification of melts and to introduce new concepts within this exciting research field in order to fulfil the challenges of the future in the field of undercooled melts.

A comprehensive description of the science and applications of the undercooling phenomenon is given. It is composed of several main parts: experimental techniques for undercooling; characterization of the undercooled melt as the first step in rapid solidification; introducing the concepts of modern theories of rapid dendrite and eutectic growth and their comparison with experimental results, and a survey of metastable materials formed from the non-equilibrium state of an undercooled melt.
* Showing clear links to possible application of results obtained from basic research
* The subject matter is multidisciplinary and will be of interest to material scientists, physicists, physical chemists, mechanical and electrical engineers

As product specifications become more demanding, manufacturers require steel with ever more specific functional properties. As a result, there has been a wealth of research on how those properties emerge during steelmaking. Fundamentals of metallurgy summarises this research and its implications for manufacturers.
The first part of the book reviews the effects of processing on the properties of metals with a range of chapters on such phenomena as phase transformations, types of kinetic reaction, transport and interfacial phenomena. Authors discuss how these processes and the resulting properties of metals can be modelled and predicted. Part two discusses the implications of this research for improving steelmaking and steel properties.
With its distinguished editor and international team of contributors, Fundamentals of metallurgy is an invaluable reference for steelmakers and manufacturers requiring high-performance steels in such areas as automotive and aerospace engineering. It will also be useful for those dealing with non-ferrous metals and alloys, material designers for functional materials, environmentalists and above all, high technology industries designing processes towards materials with tailored properties.
Summarises key research and its implications for manufacturersEssential reading for steelmakers and manufacturersWritten by leading experts from both industry and academia

"Perovskite-Based Solar Cells: From Fundamentals to Tandem Devices" gives fundamental understanding of perovskite solar cells from the chemical composition of each thin layer composing the different stacks to the whole device. Special attention has been given to the development of the materials forming the perovskite solar cell and their effect on the device performance, in addition to the recent progress of this emerging technology. Moreover, light has been shed on the perovskite elaboration techniques, in addition to the several techniques proposed to improve both the efficiency and the stability of perovskite solar cells. Furthermore, special emphasis was given to the three types of tandem solar cells and their recent advances starting from Perovskite/perovskite tandem solar cells to Perovskite/ CIGS tandem cells to perovskite/ heterojunction silicon tandem solar cells. The latter constitute a promising solution to improve photovoltaic solar cells performance.