Abstract and subjects
► The strain-induced FCC → HCP phase transformation in a cobalt-based superalloy was investigated with neutron-diffraction experiments and with in-situ loading ► The transformation onset and the accumulation rate for each loading case were quantified for monotonic tension, monotonic compression, high-cycle fatigue, and low-cycle fatigue, respectively ► The dissipation of the hysteresis energy by microstructural changes may not always be negligible for modeling the temperature evolution during mechanical deformation
The strain-induced face-centered cubic (FCC)
→
hexagonal-close packed (HCP) phase transformation in a cobalt-based superalloy was investigated with four in situ loading neutron-diffraction experiments: monotonic tension, monotonic compression, high-cycle fatigue, and low-cycle fatigue. The transformation onsets for the four respective cases were 685
MPa, 698
MPa, 1 cycle, and 3 cycles, respectively. The HCP phase accumulated at rates of 0.1
wt.%-MPa
−1 and 0.05
wt.%-MPa
−1 for the tension and compression cases, respectively. For the cyclic-loading cases, the accumulation rates were found to be inversely proportional to the number of fatigue cycles. The results under the different loading modes suggest that the phase transformation occurs according to a tensile plastic-work criterion.