Effect of stress amplitude on damage and fracture characteristics of austenitic heat-resistant steel Sanicro 25 at 973 K

High-temperature damage characteristics related to the deformation behavior of Sanicro 25 alloy were investigated under stress-controlled cyclic loading. The results show that the strain curves exhibited creep-like strain characteristics. The increase in mean stress increased the strain rate and weakened the life. Comparatively, the increase in stress amplitude only accelerated the tertiary-regime strain rate, leading to a decrease in life and fracture strain. Microcrack initiation at grain boundaries and primary Z phases at different stress amplitudes can be evidenced by the observation of micro-voids and high geometrically necessary dislocation densities around them. Subsequently, the increase in stress amplitude can significantly affect crack propagation. Dislocation accumulation at the transgranular crack tip caused by cyclic stress can assist the propagation of the transgranular crack at higher stress amplitude (& sigma;a=130MPa$$ {\sigma}_a=130\ \mathrm{MPa} $$). Conversely, transgranular cracks are easily suppressed and stop propagating at grain boundaries under constant loading (& sigma;a=0MPa$$ {\sigma}_a=0\ \mathrm{MPa} $$). The main reason was that the stress concentration of the transgranular crack tip at grain boundaries was dissipated through discontinuous dynamic recrystallization.

Automated summary

The high-temperature damage characteristics of Sanicro 25 alloy under stress-controlled cyclic loading were investigated. The strain curves exhibited creep-like strain characteristics. The increase in mean stress increased the strain rate and weakened the life, while the increase in stress amplitude only accelerated the tertiary-regime strain rate, leading to a decrease in life and fracture strain. Microcrack initiation and primary Z phases were observed at different stress amplitudes.