材料科学
金属间化合物
挤压
均质化(气候)
降水
沉淀硬化
合金
溶解
冶金
微观结构
晶界
热机械加工
表征(材料科学)
复合材料
化学工程
纳米技术
工程类
气象学
生物
物理
生态学
生物多样性
作者
John S. Aristeidakis,Gregory N. Haidemenopoulos,Ruben Bjørge,Calin D. Marioara,H. Kamoutsi,Evangelos Giarmas,Nikolaos Rafailidis
出处
期刊:Materials
[Multidisciplinary Digital Publishing Institute]
日期:2024-01-23
卷期号:17 (3): 545-545
被引量:4
摘要
Desirable properties including strength, ductility and extrudability of 6060 Al-alloys are highly dependent on processing to control the development of microstructural features. In this study, the process chain of an extrudable 6060 Al-alloy was modeled in an Integrated Computational Materials Engineering framework and validated experimentally via quantitative SEM-EDX and TEM. All critical processing stages were considered including casting, homogenization heating and holding, extrusion cooling and two-stage aging. Segregation and intermetallics formation were accurately predicted and experimentally verified in the as-cast condition. Diffusion simulations predicted the dissolution of intermetallics and completion of β-AlFeSi to α-AlFeSi transformation during homogenization, in excellent agreement with quantitative SEM-EDX characterization. Precipitation simulations predicted the development of a β″ strengthening dispersion during extrusion cooling and aging. Needle-shaped β″ precipitates were observed and analyzed with quantitative high-resolution TEM, validating predictions. Ensuing precipitation strengthening was modeled in terms of aging time, presenting good agreement with yield strength measurements. Precipitate-Free Zones and coarse, metastable β-type particles on dispersoids and grain boundaries were investigated. The proposed integrated modeling and characterization approach considers all critical processing stages and could be used to optimize processing of extrudable 6xxx Al-alloys, providing insight to mechanisms controlling microstructural evolution and resulting properties.
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