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Books on the topic 'Solidification structure'

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Author: Grafiati

Published: 10 December 2022

Last updated: 28 January 2023

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1

Minkoff, I. Solidification and cast structure. Chichester [West Sussex]: Wiley, 1986.

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2

E, Loper David, ed. Structure and dynamics of partially solidified systems. Dordrecht: Martinus Nijhoff Publishers, 1987.

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3

Tekkō Kiso Kyōdō Kenkyūkai. Tekkō no Kyūsoku Gyōko Bukai. Kyūsoku gyōko soshiki shashinshū: Collected photographs of structures of rapidly solidified materials. Tōkyō: Nihon Tekkō Kyōkai, 1989.

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4

Jones, I. A. Procedures for reducing solidification cracking in CO2 laser welds in structural steel. Cambridge: TWI, 1999.

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5

Li, Jiang-shan. Evolution Mechanism on Structural Characteristics of Lead-Contaminated Soil in the Solidification/Stabilization Process. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-13-1193-2.

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6

ASM Materials Week '86 (1986 Orlando, Fla.). Processing of structural metals by rapid solidification: Proceedings of a seven session symposium on Enhanced Properties in Structural Metals via Rapid Solidification sponsored by the Materials Processing Committee of ASM's Materials Science Division held at Materials Week '86, Orlando, Fla., 6-9 October 1986. [Metals Park, Ohio]: ASM International, 1987.

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7

Rohatgi Honorary Symposium (2006 San Antonio, Tex.). Solidification processing of metal matrix composites: Rohatgi Honorary Symposium : proceedings of a symposium sponsored by the Solidification Committee of the Materials Processing & Manufacturing Division (MPMD) and the Composite Materials Committee of the Structural Materials Division (SMD) of TMS (The Minerals, Metals & Materials Society), held during the TMS Annual Meeting in San Antonio, Texas, USA, March 12-16, 2006. Warrendale, Pennsylvania: TMS, 2006.

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8

L, Regelʹ L., and United States. National Aeronautics and Space Administration., eds. Modelling directional soldification: Progress report on grant NAG8-831, 1 May 1991 to 31 October 1992. Potsdam, N.Y: Clarkson University, 1991.

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9

United States. National Aeronautics and Space Administration., ed. Modelling directional soldification: Second semi-annual progress report, 1 November 1990 to 30 April 1991. Potsdam, N.Y: Clarkson University, 1991.

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10

United States. National Aeronautics and Space Administration., ed. Modelling directional soldification: Fourth semi-annual progress report, 1 March 1987 to 31 August 1987. Potsdam, N.Y: Clarkson University, 1987.

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11

L, Regel £. L., and United States. National Aeronautics and Space Administration., eds. Modelling directional soldification: Progress report on grant NAG8-831, 1 May 1991 to 31 October 1992. Potsdam, N.Y: Clarkson University, 1991.

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12

1949-, Liebermann Howard H., ed. Rapidly solidfied alloys: Processes, structures, properties, applications. New York: M. Dekker, 1993.

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13

Froes, F. H. Processing of Structural Metals by Rapid Solidification (Conference proceedings). Asm Intl, 1989.

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14

H, Froes F., Savage S. J, and American Society for Metals. Materials Processing Committee., eds. Processing of structural metals by rapid solidification: Proceedings of a seven session symposium on enhanced properties in structural metals via rapid solidification. [Metals Park, Ohio]: ASM International, 1987.

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15

Li, Jiang-shan. Evolution Mechanism on Structural Characteristics of Lead-Contaminated Soil in the Solidification/Stabilization Process. Springer, 2018.

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16

Li, Jiang-shan. Evolution Mechanism on Structural Characteristics of Lead-Contaminated Soil in the Solidification/Stabilization Process. Springer, 2018.

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17

Cantor, Brian. The Equations of Materials. Oxford University Press, 2020. http://dx.doi.org/10.1093/oso/9780198851875.001.0001.

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This book describes some of the important equations of materials and the scientists who derived them. It is aimed at anyone interested in the manufacture, structure, properties and engineering application of materials such as metals, polymers, ceramics, semiconductors and composites. It is meant to be readable and enjoyable, a primer rather than a textbook, covering only a limited number of topics and not trying to be comprehensive. It is pitched at the level of a final year school student or a first year undergraduate who has been studying the physical sciences and is thinking of specialising into materials science and/or materials engineering, but it should also appeal to many other scientists at other stages of their career. It requires a working knowledge of school maths, mainly algebra and simple calculus, but nothing more complex. It is dedicated to a number of propositions, as follows: 1. The most important equations are often simple and easily explained; 2. The most important equations are often experimental, confirmed time and again; 3. The most important equations have been derived by remarkable scientists who lived interesting lives. Each chapter covers a single equation and materials subject. Each chapter is structured in three sections: first, a description of the equation itself; second, a short biography of the scientist after whom it is named; and third, a discussion of some of the ramifications and applications of the equation. The biographical sections intertwine the personal and professional life of the scientist with contemporary political and scientific developments. The topics included are: Bravais lattices and crystals; Bragg’s law and diffraction; the Gibbs phase rule and phases; Boltzmann’s equation and thermodynamics; the Arrhenius equation and reactions; the Gibbs-Thomson equation and surfaces; Fick’s laws and diffusion; the Scheil equation and solidification; the Avrami equation and phase transformations; Hooke’s law and elasticity; the Burgers vector and plasticity; Griffith’s equation and fracture; and the Fermi level and electrical properties.

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18

Lampman, Steve, ed. Weld Integrity and Performance. ASM International, 1997. http://dx.doi.org/10.31399/asm.tb.wip.9781627083591.

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Weld Integrity and Performance is a convenient reference and sourcebook for anyone involved in the application, fabrication, or assessment of welded structures. It provides detailed information on relevant topics including weld solidification, weldability testing, weld characterization, discontinuities and imperfections, cracking phenomena, inspection and evaluation techniques, fatigue and fracture control, fracture mechanics, fitness-for-service testing, repair welding, and weld corrosion. An entire section, the largest by far in the book, covers the basic metallurgy and engineering properties of weldments made from carbon and low-alloy steels, stainless steels, aluminum alloys, titanium alloys, nickel-base alloys, and refractory metals, including tantalum, niobium, molybdenum, and tungsten alloys. The book also provides insights into the origins of failure associated with different welding processes and includes an appendix with information on the weldability of common alloys (including cast irons) as well as process selection guidelines, recommended preheat and interpass temperatures and postweld heat treatments for pipe welds and pressure vessels, and qualification codes and standards. For information on the print version, ISBN 978-0-87170-600-8, follow this link.

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