Study on notch fracture of TiAl alloys at room temperature |
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Authors: | J H Chen G Z Wang R Cao J Zhang |
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Affiliation: | (1) the State Key Laboratory for New Non-Ferrous Materials, Lanzhou University of Science and Technology (Gansu University of Technology), 730050 Lanzhou, China;(2) the High Temperature Material Research Division, Central Iron and Steel Research Institute, Beijing, P.R. China |
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Abstract: | In-situ observations of fracture processes combined with one-to-one observations of fracture surfaces and finite-element method (FEM)
calculations are carried out on notched tensile specimens of two-phase polycrystalline TiAl alloys. The results reveal that
most cracks are initiated and propagated along the interfaces between lamellae before plastic deformation. The driving force
for the fracture process is the tensile stress, which is consistent with a previous study.1] In specimens with a slit notch, most cracks are initiated directly from the notch root and extended along lamellar interfaces.
The main crack can be stopped or deflected into a delamination mode by a barrier grain with a lamellar interface orientation
deviated from the direction of crack propagation. In this case, new cracks are nucleated along lamellar interfaces of grains
with favorable orientation ahead of the barrier grain. The main crack and a new crack are then linked by the translamellar
cleavage fracture of the barrier grain with increasing applied load. In order to extend the main crack, further increases
of the applied load are needed to move the high stress region into the ligament until catastrophic fracture. The FEM calculations
reveal that the strength along lamellar interfaces (interlamellar fracture) is as low as 50 MPa and appreciably lower than
the strength perpendicular to the lamellae (translamellar fracture), which shows a value higher than 120 MPa. This explains
the reason why cracks nucleate and preferably extend along the lamellar interfaces. |
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