Irradiation embrittlement characterization of the EUROFER 97 material

The paper summarizes original results of irradiation embrittlement study of EUROFER 97 material that has been proposed as one candidate of structural materials for future fusion energy systems and GEN IV. pecimens were manufactured from base metal as well as from weld metal and tested in initial unirradiated condition and also after neutron irradiation. ation embrittlement was characterized by testing of toughness properties at transition temperature region – static fracture toughness and dynamic fracture toughness properties, all in sub-size three-point bend specimens (27 × 4 × 3 mm3). Testing and evaluation was performed in accordance with ASTM and ESIS standards, fracture toughness KJC and KJd data were also evaluated with the “Master curve” approach. Moreover, J–R dependencies were determined and analyzed. per compares unirradiated and irradiated properties as well as changes in transition temperature shifts of these material parameters. Discussion about the correlation between static and dynamic properties is also given. s from irradiation of EUROFER 97 show that this steel – base metal as well as weld metal – is suitable as a structural material for reactor pressure vessels of innovative nuclear systems – fusion energy systems and GEN IV. Transition temperature shifts after neutron irradiation by 2.5 dpa dose show a good agreement in the case of EUROFER 97 base material for both static and dynamic fracture toughness tests. From the results it can be concluded that there is a low sensitivity of weld metal to neutron irradiation embrittlement in comparison with EUROFER 97 base metal.