Study of the Precipitation Kinetics, Microstructures, and Mechanical Properties of Al-Zn-Mg-xCu Alloys

Microstructures and mechanical properties of Al-5Zn-2.6Mg alloys with 0.24, 0.43, and 0.91 wt.% Cu were studied and the precipitation rate and activation energy at 378, 393, and 408 K were calculated using the Arrhenius equation in this work. The aging reaction rate k increased and the precipitation...

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Published inMetals (Basel ) Vol. 12; no. 10; p. 1610
Main Authors Tian, Aiqin, Sun, Lin, Deng, Yunlai, Yuan, Manfa
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2022
Subjects
Activation energy
Aging
Aging (metallurgy)
Al-Zn-Mg-Cu alloy
Alloys
Aluminum alloys
Aluminum base alloys
Copper
Corrosion
Crack initiation
Crack propagation
Dimpling
Elongation
Grain boundaries
Intergranular fracture
Magnesium
Manganese
Mechanical properties
Microstructure
Morphology
Precipitates
Precipitation hardening
precipitation kinetics
Solid solutions
Solution strengthening
Specialty metals industry
Tensile strength
Transgranular fracture
Yield stress
Zinc
Zinc compounds
United Kingdom
Online AccessGet full text
ISSN2075-4701
2075-4701
DOI10.3390/met12101610

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Abstract Microstructures and mechanical properties of Al-5Zn-2.6Mg alloys with 0.24, 0.43, and 0.91 wt.% Cu were studied and the precipitation rate and activation energy at 378, 393, and 408 K were calculated using the Arrhenius equation in this work. The aging reaction rate k increased and the precipitation activation energy Ea decreased from 25.7 to 15.0 kJ/mol. The η’ distribution density of the precipitates clearly increased with increasing Cu content. However, the size and number of coarse second phase with Fe and Mn impurities also increased, which increased the tendency for crack initiation and propagation at the grain boundary, resulting in a decrease in dimple area. The fracture morphology transformed from plastic transgranular fracture to brittle intergranular fracture and the elongation of the alloys decreased by 3.8%. The contribution of Cu content to yield strength was predominantly due to precipitation strengthening rather than grain boundary strengthening and solid solution strengthening. The tensile strength of the Al-5Zn-2.6Mg alloys with 0.91 wt.% Cu subject to peak aging at 393 K increased by 10.2%.
AbstractList Microstructures and mechanical properties of Al-5Zn-2.6Mg alloys with 0.24, 0.43, and 0.91 wt.% Cu were studied and the precipitation rate and activation energy at 378, 393, and 408 K were calculated using the Arrhenius equation in this work. The aging reaction rate k increased and the precipitation activation energy Ea decreased from 25.7 to 15.0 kJ/mol. The η’ distribution density of the precipitates clearly increased with increasing Cu content. However, the size and number of coarse second phase with Fe and Mn impurities also increased, which increased the tendency for crack initiation and propagation at the grain boundary, resulting in a decrease in dimple area. The fracture morphology transformed from plastic transgranular fracture to brittle intergranular fracture and the elongation of the alloys decreased by 3.8%. The contribution of Cu content to yield strength was predominantly due to precipitation strengthening rather than grain boundary strengthening and solid solution strengthening. The tensile strength of the Al-5Zn-2.6Mg alloys with 0.91 wt.% Cu subject to peak aging at 393 K increased by 10.2%.
Microstructures and mechanical properties of Al-5Zn-2.6Mg alloys with 0.24, 0.43, and 0.91 wt.% Cu were studied and the precipitation rate and activation energy at 378, 393, and 408 K were calculated using the Arrhenius equation in this work. The aging reaction rate k increased and the precipitation activation energy E[sub.a] decreased from 25.7 to 15.0 kJ/mol. The η’ distribution density of the precipitates clearly increased with increasing Cu content. However, the size and number of coarse second phase with Fe and Mn impurities also increased, which increased the tendency for crack initiation and propagation at the grain boundary, resulting in a decrease in dimple area. The fracture morphology transformed from plastic transgranular fracture to brittle intergranular fracture and the elongation of the alloys decreased by 3.8%. The contribution of Cu content to yield strength was predominantly due to precipitation strengthening rather than grain boundary strengthening and solid solution strengthening. The tensile strength of the Al-5Zn-2.6Mg alloys with 0.91 wt.% Cu subject to peak aging at 393 K increased by 10.2%.
Audience Academic
Author Deng, Yunlai
Yuan, Manfa
Sun, Lin
Tian, Aiqin
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Snippet Microstructures and mechanical properties of Al-5Zn-2.6Mg alloys with 0.24, 0.43, and 0.91 wt.% Cu were studied and the precipitation rate and activation...
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SubjectTerms Activation energy
Aging
Aging (metallurgy)
Al-Zn-Mg-Cu alloy
Alloys
Aluminum alloys
Aluminum base alloys
Copper
Corrosion
Crack initiation
Crack propagation
Dimpling
Elongation
Grain boundaries
Intergranular fracture
Magnesium
Manganese
Mechanical properties
Microstructure
Morphology
Precipitates
Precipitation hardening
precipitation kinetics
Solid solutions
Solution strengthening
Specialty metals industry
Tensile strength
Transgranular fracture
Yield stress
Zinc
Zinc compounds
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Title Study of the Precipitation Kinetics, Microstructures, and Mechanical Properties of Al-Zn-Mg-xCu Alloys
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https://doaj.org/article/8fdbf9d6ea0f49729b18f1dfceaf5f92
Volume 12
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