Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
7951841 | Journal of Materials Science & Technology | 2018 | 9 Pages |
Abstract
The recent studies had focused on the fatigue crack propagation behaviors of αâ¯+â¯Î² titanium alloys with Widmanstatten microstructure. The fascinated interest of this type of microstructure is due to the superior fatigue crack propagation resistance and fracture toughness as compared to other microstructures, which was believed to be related to the fatigue crack tip plastic zone (CTPZ). In this study, the plastic deformation in fatigue CTPZ of Ti-6Al-4V titanium alloy with Widmanstatten microstructure was characterized by scanning electron microscope (SEM) and electron backscatter diffraction (EBSD). The results showed that large-scale slipping and deformation twinning were generated in fatigue CTPZ due to the crystallographic feature of the Widmanstatten microstructure. The activation of twinning was related to the rank of Schmid factor (SF) and the diversity of twin variants developing behaviors reflected the influence of SF rank. The sizes of CTPZ under different stress intensity factors (K) were examined by the white-light coherence method, and the results revealed that the range of the plastic zone is enlarged with the increasing K (or crack length), while the plastic strain decreased rapidly with the increasing distance from the crack surface. The large-scale slipping and deformation twinning in Widmannstatten microstructure remarkably expanded the range of fatigue CTPZ, which would lead to the obvious larger size of the observed CTPZ than that of the theoretically calculated size.
Related Topics
Physical Sciences and Engineering
Materials Science
Materials Chemistry
Authors
Yingjie Ma, Sabry S. Youssef, Xin Feng, Hao Wang, Sensen Huang, Jianke Qiu, Jiafeng Lei, Rui Yang,