Ambient- to Elevated-Temperature Fracture and Fatigue Properties of Mo-Si-B Alloys: Role of Microstructure

摘要

Ambient- to elevated-temperature fracture and fatigue-crack growth results are presented for five Mo-Mo_3Si-Mo_5SiB_2-containing a-Mo matrix (17 to 49 vol pct) alloys, which are compared to results for intermetallic-matrix alloys with similar compositions. By increasing the a-Mo volume fraction, ductility, or microstructural coarseness, or by using a continuous a-Mo matrix, it was found that improved fracture and fatigue properties are achieved by promoting the active toughening mechanisms, specifically crack trapping and crack bridging by the a-Mo phase. Crack-initiation fracture toughness values increased from 5 to 12 MPavm with increasing a-Mo content from 17 to 49 vol pet, and fracture toughness values rose with crack extension, ranging from 8.5 to 21 M PaV m at ambient temperatures. Fatigue thresholds benefited similarly from more a-Mo phase, and the fracture and fatigue resistance was improved for all alloys tested at 1300 deg C, the latter effects being attributed to improved ductility of the a-Mo phase at elevated temperatures.