Mn自旋极化增强Mg的晶界滑动

Chemical Engineering (Engineering) eJournal Pub Date : 2021-04-06 DOI:10.2139/ssrn.3820201

V. Wang, Jun-ping Du, H. Somekawa, S. Ogata, W. Geng

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摘要

已知稀土合金元素的偏析在Mg中偏析到晶界，并通过强化学键抑制晶界滑动。然而，锰的偏析最近被发现可以增强镁的晶界滑动，从而提高其延展性。以Mg(-2114)孪晶界为例，对该晶界上Y、Zn、Mn的偏析和化学键进行了第一性原理对比研究。我们发现Y-4d态和Mn-3d态都与Mg-3sp态杂化，而Zn-Mg键仅以电荷转移为特征。Mn的强自旋极化推动了自旋向上的三维态下移，导致Mn- mg键的各向异性减少，孪晶界处电荷分布偏多，从而促进了晶界的可塑性，如晶界滑动。

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Spin Polarization of Mn Enhances Grain Boundary Sliding in Mg

Segregation of rare earth alloying elements are known to segregate to grain boundaries in Mg and suppress grain boundary sliding via strong chemical bonds. Segregation of Mn, however, has recently been found to enhance grain boundary sliding in Mg and thereby boosting its ductility. Taking the Mg (-2114) twin boundary as an example, we have performed a first-principles comparative study on the segregation and chemical bonding of Y, Zn, and Mn at this boundary. We find that both Y-4d and Mn-3d states hybridize with the Mg-3sp states, while Zn-Mg bonding is characterized by charge transfer only. Strong spin-polarization of Mn pushes the up-spin 3d states down, leading to less anisotropic Mn-Mg bonds with more delocalized charge distribution at the twin boundary, and thus promotes grain boundary plasticity, e.g., grain boundary sliding.

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Chemical Engineering (Engineering) eJournal

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