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Metals --- Electroplating. --- Electrochemistry, Industrial. --- Electrochemistry --- Industrial electrochemistry --- Chemistry, Technical --- Electrodeposition of metals --- Plating --- Hydrogen embrittlement of metals --- Gases in metals --- Hydrogen --- Hydrogen content. --- Hydrogen embrittlement. --- Industrial applications --- Finishing --- Embrittlement --- Hydrogen content

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By drawing together the current theoretical and experimental understanding of the phenomena of delayed hydride cracking (DHC) in zirconium alloys, The Effect of Hydrogen and Hydrides on the Integrity of Zirconium Alloy Components: Delayed Hydride Cracking provides a detailed explanation focusing on the properties of hydrogen and hydrides in these alloys. Whilst the focus lies on zirconium alloys, the combination of both the empirical and mechanistic approaches creates a solid understanding that can also be applied to other hydride forming metals.   This up-to-date reference focuses on documented research surrounding DHC, including current methodologies for design and assessment of the results of periodic in-service inspections of pressure tubes in nuclear reactors. Emphasis is placed on showing that our understanding of DHC is supported by progress across a broad range of fields. These include hysteresis associated with first-order phase transformations; phase relationships in coherent crystalline metallic solids; diffusion of substitutional and interstitial atoms in crystalline solids; and continuum fracture and solid mechanics. Furthermore, an account of current methodologies is given, illustrating how such understanding of hydrogen, hydrides and DHC in zirconium alloys underpins these methodologies for assessments of real life cases in the Canadian nuclear industry.   The all-encompassing approach makes The Effect of Hydrogen and Hydrides on the Integrity of Zirconium Alloy Component: Delayed Hydride Cracking an ideal reference source for students, researchers and industry professionals alike.

Engineering. --- Nuclear reactors -- Materials. --- Zirconium alloys -- Fracture. --- Zirconium alloys -- Hydrogen content. --- Chemical & Materials Engineering --- Engineering & Applied Sciences --- Electrical & Computer Engineering --- Electrical Engineering --- Materials Science --- Applied Mathematics --- Zirconium alloys --- Nuclear reactors --- Hydrogen content. --- Fracture. --- Materials. --- Nuclear energy. --- Chemical engineering. --- Continuum mechanics. --- Nuclear engineering. --- Metals. --- Continuum Mechanics and Mechanics of Materials. --- Industrial Chemistry/Chemical Engineering. --- Metallic Materials. --- Nuclear Engineering. --- Nuclear Energy. --- Metallic elements --- Chemical elements --- Ores --- Metallurgy --- Atomic power engineering --- Engineering --- Nuclear physics --- Nuclear energy --- Mechanics of continua --- Elasticity --- Mechanics, Analytic --- Field theory (Physics) --- Chemistry, Industrial --- Engineering, Chemical --- Industrial chemistry --- Chemistry, Technical --- Atomic energy --- Atomic power --- Energy, Atomic --- Energy, Nuclear --- Nuclear power --- Power, Atomic --- Power, Nuclear --- Force and energy --- Power resources --- Nuclear engineering --- Nuclear facilities --- Nuclear power plants --- Construction --- Industrial arts --- Technology --- Gases in metals --- Hydrogen --- Mechanics. --- Mechanics, Applied. --- Solid Mechanics. --- Engineering materials --- Industrial materials --- Engineering design --- Manufacturing processes --- Applied mechanics --- Engineering, Mechanical --- Engineering mathematics --- Classical mechanics --- Newtonian mechanics --- Physics --- Dynamics --- Quantum theory --- Materials