Nucleation and Growth of Fe-Rich Phases in Al-5Ti-1B Modified Al-Fe Alloys Using Synchrotron X-Ray Imaging and Electron Microscopy

Other Topics Engineering Research eJournal Pub Date : 2020-09-17 DOI:10.2139/ssrn.3675734

Yuliang Zhao, Weiweng Zhang, D. Song, B. Lin, Fanghua Shen, Donghai Zheng, C. Xie, Zhenzhong Sun, Ya-nan Fu, Runxia Li

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Abstract

The plate-like Fe-rich intermetallic phases directly influence the mechanical properties of recycled Al alloys, thus many attempts have been made to modify their morphology. Here, through synchrotron X-ray imaging and electron microscopy, we reveal the underlying nucleation and growth mechanism of Fe-rich phases during the solidification of Al-5Ti-1B inoculated Al-2Fe alloys. The experiment results shown that Al-5Ti-1B grain refiner and applied pressure both reduce the sizes and number of primary Al 3Fe phases, and promote the formation of eutectic Al6Fe phases. The tomography results shown that Al-5Ti-1B change the 3D morphology of primary Fe-rich phases from rod-like to branched plate-like and reduced their thickness and size. This is attributed to the Ti-containing solutes in the melts retard the diffusion of Fe atoms and the TiB2 provide possible nucleation sites for Al6Fe phases. The nucleation mechanism of Fe-rich phases is discussed in terms of experimental observation and E2EM model. It is suggested that the V segregated at the TiB2/Al6Fe interface and lower their mismatch and promote the transformation from Al3Fe to Al6Fe phases.

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Al-5Ti-1B改性Al-Fe合金中富铁相的形核和生长

片状富铁金属间相直接影响再生铝合金的力学性能，因此人们对其形貌进行了许多改变。通过同步x射线成像和电镜技术，揭示了Al-5Ti-1B接种Al-2Fe合金凝固过程中富铁相的形核和生长机制。实验结果表明，Al- 5ti - 1b晶粒细化剂和施加压力均能减小初生al3fe相的尺寸和数量，促进共晶Al6Fe相的形成。层析成像结果表明，Al-5Ti-1B使富铁初生相的三维形貌由棒状变为支片状，并减小了它们的厚度和尺寸。这是由于熔体中含有ti的溶质阻碍了Fe原子的扩散，而TiB2为Al6Fe相提供了可能的成核位置。根据实验观察和E2EM模型，讨论了富铁相的成核机理。结果表明，V在TiB2/Al6Fe界面处偏析，降低了两者的失配，促进了Al3Fe相向Al6Fe相的转变。

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Other Topics Engineering Research eJournal

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