晶粒尺寸对纳米晶多主元素合金变形的影响

A. Roy, R. Devanathan, Duane D. Johnson, G. Balasubramanian
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引用次数: 9

摘要

多主元素合金(MPEA)由于其卓越的力学性能,特别是在高温下,继续引起人们的兴趣。在这里,我们研究了一种具有代表性的纳米晶耐火MPEA,并确定了从Hall-Petch到逆Hall-Petch关系的交叉。虽然所考虑的MPEA主要采用单相BCC晶格,但晶界的存在赋予非晶相分布随着晶粒尺寸的减小而增加(即晶界体积分数的增加)。通过分子动力学模拟,我们发现MPEA的屈服强度随着平均晶粒尺寸的减小而增加,但低于临界晶粒尺寸<23.2 nm屈服强度降低。这种变形行为的变化是由位错滑移向晶界滑移转变所驱动的。结果表明,当位错密度达到最大值时,由Hall-Petch向逆Hall-Petch转变与晶界位错堆积有关。
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Grain-Size Effects on the Deformation in Nanocrystalline Multi-Principal Element Alloy
Multi-principal element alloys (MPEAs) continue to garner interest due to their remarkable mechanical properties, especially at elevated temperatures. Here, we examine a representative nanocrystalline refractory MPEA and identify a crossover from a Hall-Petch to inverse-Hall-Petch relation. While the considered MPEA predominantly assumes a single-phase BCC lattice, the presence of grain boundaries imparts amorphous phase distributions that increase with decreasing grain size (i.e., increasing grain boundary volume fraction). Using molecular dynamics simulations, we find that the yield strength of the MPEA increases with decreasing average grain size, but below a critical grain size < 23.2 nm the yield strength decreases. This change in the deformation behavior is driven by the transition from dislocation slip to grain-boundary slip as the predominant mechanism. Our results reveal that the change from Hall-Petch to inverse-Hall-Petch regime is correlated to dislocation stacking at the grain boundary when dislocation density reaches a maximum.
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