Fracture and fatigue-crack growth behavior in ductile-phase toughened molybdenum disilicide: Effects of niobium wire vs particulate reinforcements
- Univ. of California, Berkeley, CA (United States). Dept. of Materials Science and Mineral Engineering
A study has been made of the fracture toughness/resistance-curve (R-curve) and cyclic fatigue-crack propagation behavior in a molybdenum disilicide composite, ductile-phase toughened with nominally 20 vol pct Nb-wire mesh reinforcements (Nb{sub m}/MoSi{sub 2}); results are compared with monolithic MoSi{sub 2} and MoSi{sub 2} reinforced with 20 vol pct spherical Nb particles (Nb{sub p}/MoSi{sub 2}). It is found that the high aspect ratio wire reinforcements induce significant toughening in MoSi{sub 2}, both under monotonic and cyclic fatigue loading conditions. Specifically, the Nb{sub m}/MoSi{sub 2} composite exhibits R-curve behavior with a steady-state fracture toughness of {approximately}13 MPa{radical}m, compared to unstable fracture at K{sub c} values below 5 MPa{radical}m in unreinforced MoSi{sub 2} or Nb{sub p}/MoSi{sub 2}. Such behavior is seen to be associated with extensive crack deflection within the reaction layer between Nb and the matrix, which leads to crack bridging by the unbroken ductile phase. Similarly, resistance to fatigue-crack growth is found to be far superior in the wire-reinforced composite over pure MoSi{sub 2} and Nb{sub p}/MoSi{sub 2}. Although crack paths are again characterized by extensive deflection along the Nb/matrix reaction layer, the role of crack bridging is diminished under cyclic loading due to fatigue failure of the Nb. Instead, the superior fatigue properties of the Nb{sub m}/MoSi{sub 2} composite are found to be associated with high levels of crack closure that result from highly deflected crack paths along the (Nb,Mo){sub 5}Si{sub 3} reaction layer interface.
- Sponsoring Organization:
- USDOE
- OSTI ID:
- 438543
- Journal Information:
- Metallurgical and Materials Transactions. A, Physical Metallurgy and Materials Science, Journal Name: Metallurgical and Materials Transactions. A, Physical Metallurgy and Materials Science Journal Issue: 12 Vol. 27; ISSN MMTAEB; ISSN 1073-5623
- Country of Publication:
- United States
- Language:
- English
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