Tensile and low cycle fatigue properties of EUROFER97-steel after 16.3 dpa neutron irradiation at 523, 623 and 723 K

Abstract

Neutron-irradiated specimens of the reduced-activation tempered martensitic steel EUROFER97 were tested by tensile and low cycle conditions to detect the impact of irradiation on strength and lifetime. The irradiation temperature ranged from 523 to 723K with an accumulated dose of up to 16.3dpa. Tensile tests revealed a significant irradiation-induced hardening below 673K with a peak of ∼430MPa at 573K but none was seen at 723K, as expected. Despite the significant irradiation-induced reduction of uniform elongation, the total elongation is only reduced by about 50% below 673K. Post-irradiation strain-controlled fatigue tests have been carried out at Tirrad=Ttest=523, 623 and 723K. Pronounced cyclic softening was observed in all specimens. At 623 and 723K, neutron irradiation had no effect on fatigue life within the data scatter. A significant lifetime increase has been observed at Tirrad=Ttest=523K that advances with decreasing stress amplitude Δε (1%→0.5%) up to a factor of ten. Scanning electron microscopy (SEM) analysis revealed ductile fracture and fatigue striations on the fracture surfaces. After push–pull fatigue testing, transmission electron microscopy (TEM) investigations showed the typical sub-cell formation, even at Tirrad=Ttest=523K.