材料科学
晶体孪晶
电子背散射衍射
高熵合金
微观结构
应变硬化指数
合金
硬化(计算)
立方晶系
透射电子显微镜
可塑性
变形(气象学)
复合材料
衍射
打滑(空气动力学)
凝聚态物理
结晶学
热力学
光学
纳米技术
物理
化学
图层(电子)
作者
Matthias Bönisch,Y. Wu,Hüseyin Şehitoğlu
标识
DOI:10.1038/s41598-018-28784-1
摘要
dual-phase high entropy alloy (HEA) was plastically strained in uniaxial compression at 77K and 293K and the underlying deformation mechanisms were studied. The undeformed microstructure consists of a body-centered-cubic (bcc)/B2 interdendritic network and precipitates embedded in 〈001〉-oriented fcc dendrites. In contrast to other dual-phase HEAs, at both deformation temperatures a steep rise in the stress-strain curves occurs above 23% total axial strain. As a result, the hardening rate associated saturates at the unusual high value of ~6 GPa. Analysis of the strain partitioning between fcc and bcc/B2 by digital image correlation shows that the fcc component carries the larger part of the plastic strain. Further, electron backscatter diffraction and transmission electron microscopy evidence ample fcc deformation twinning both at 77K and 293K, while slip activity only is found in the bcc/B2. These results may guide future advancements in the design of novel alloys with superior toughening characteristics.
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