Min Zheng, Tao Zheng, Weihua Chen, Dingfeng Qu, Wenyuan Chen, Zongxiao Zhu
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引用次数: 0
摘要
TiAl-Ti3Al 双相合金广泛应用于高科技领域。其界面微观结构的演变会影响合金的性能。但双相界面微观结构在外力作用下对力学性能的影响尚不清楚。为了更深入地了解 TiAl 合金并促进其广泛应用。本研究采用 MD 模拟的纳米压痕模型研究了外力作用下 γ(TiAl)/α2(Ti3Al)界面微观结构的演变。结果表明,在球形纳米压头的作用下,γ(TiAl)/α2(Ti3Al)界面微结构会阻碍界面原子的运动。原子平行于界面运动,增强了合金的抗变形能力。在压痕过程中,位错从 Ti3Al 相滑向 TiAl 相,反之亦然。此外,相位差导致弹性恢复率、剪切应变和塑性变形能力明显不同。
Effect of interfacial microstructure on TiAl-Ti3Al biphase alloy was studied via molecular dynamics
The TiAl-Ti3Al biphase alloy is widely used in high-tech fields. The evolution of its interfacial microstructure affects alloy performance. But the impact of the biphase interfacial microstructure on mechanical properties under external forces is unknown. For the purpose of attaining a more profound comprehension of TiAl alloys and facilitating their extensive employment. In this work, the evolution of the γ(TiAl)/α2(Ti3Al) interface microstructure under external force was investigated by the nanoindentation model of MD simulation. The results showed that the γ(TiAl)/α2(Ti3Al) interface microstructure can hinder the motion of interface atoms under the spherical nanoindenter’s action. The atoms moved parallel to the interface, enhancing the alloy’s deformation resistance. During indentation, dislocations slipped from the Ti3Al phase to the TiAl phase, but not vice versa. Moreover, the phase difference led to significantly different elastic recovery rates, shear strains, and plastic deformation capabilities.
期刊介绍:
Applied Physics A publishes experimental and theoretical investigations in applied physics as regular articles, rapid communications, and invited papers. The distinguished 30-member Board of Editors reflects the interdisciplinary approach of the journal and ensures the highest quality of peer review.
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