In situ micro-cantilever tests to study fracture properties of NiAl single crystals

In situ micro-cantilever tests to study fracture properties of NiAl single crystals

In situ micro-cantilever tests were carried out to determine the anisotropic fracture toughness of NiAl single crystals. Notched micro-cantilever beams with a beam length of 8μm, 1.5μm thickness and 1.8μm width were milled in so-called “hard” and “soft” orientations of NiAl using a focused ion beam....

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Bibliographic Details
Published in:Acta materialia Vol. 60; no. 3; pp. 1193 - 1200
Main Authors: Iqbal, F., Ast, J., Göken, M., Durst, K.
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 01-02-2012
Elsevier
Subjects:
Applied sciences
Exact sciences and technology
Fracture toughness
Fractures
In situ micro-cantilever testing
Mechanical properties and methods of testing. Rheology. Fracture mechanics. Tribology
Metals. Metallurgy
NiAl
Strain gradients
NiAl
In situ micro-cantilever testing
Fracture toughness
Strain gradients
In situ
In situ test
Rupture
Mechanical properties
Single crystal
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Summary:In situ micro-cantilever tests were carried out to determine the anisotropic fracture toughness of NiAl single crystals. Notched micro-cantilever beams with a beam length of 8μm, 1.5μm thickness and 1.8μm width were milled in so-called “hard” and “soft” orientations of NiAl using a focused ion beam. These cantilevers were loaded in situ with the help of a cantilever-based nanoindenter mounted inside a scanning electron microscope. A fracture toughness of 3.52±0.29MPam1/2 was obtained for the “soft” orientation and 5.12±0.50MPam1/2 for the “hard” orientation, which is in good agreement with literature values on the fracture toughness of macroscopic NiAl specimens. Furthermore, nanoindentations were performed for studying the size effects occurring at small length scales for both orientations. The applicability of the small sample geometries for testing the fracture toughness is finally discussed in terms of size effects in the flow stress of the material due to dislocation nucleation and strain gradients at the crack tip.
ISSN:1359-6454
1873-2453
DOI:10.1016/j.actamat.2011.10.060