by Yufan Zhou, Gihan Velişa, Saro San, Miguel L. Crespillo, Zhe Fan, Hongbin Bei, William J. Weber, Pengyuan Xiu, Lumin Wang, Fillip Tuomisto, Wai-Yim Ching and Yanwen Zhang
Abstract:
Understanding chemical disorder in many concentrated solid solution alloys (CSAs) at the levels of electrons and atoms has attracted increasing attention as a path forward to reveal and identify underlying mechanisms for extraordinary mechanical properties and improved radiation tolerance. Single-phase NiFeCoCr CSA is a common base for many high-entropy alloys (HEAs) that have shown improved mechanical strength and radiation tolerance. In this study, defect production and damage evolution in NiFeCoCr under ion irradiation at room temperature to dose over 20 dpa are determined using ion channeling technique along both textless100textgreater and textless110textgreater directions utilizing multiple probing beam energies. The results obtained from the multi-axial and multi-energy channeling analysis are compared with those previously obtained for Ni crystals irradiated under similar conditions. The influence of chemical complexity on defect production and clustering at early-stage under room temperature irradiation up to dose of 1 dpa is discussed based on positron annihilation spectroscopy results. Defect structure evaluation in Ni and NiFeCoCr is also discussed based on transmission electron microscopy results over a prolonged irradiation at both room and elevated temperatures. Compared with chemically complex NiFeCoCr, larger dislocation loops thus less lattice strain are expected to form in pure Ni. Moreover, the role of chemical disorder in this CSA is also investigated based on ab initio calculations using large supercells. To understand the impact of chemical complexity effect on defect structure evolution, this integrated research effort attempts to link the relatively large charge redistribution due to difference in valence electron counts resulting from alloying different 3d transition metal elements, moderate lattice distortion arising from similar adaptable atomic size, and notable suppressed or delayed damage evolution in NiFeCoCr.
Reference:
Yufan Zhou, Gihan Velişa, Saro San, Miguel L. Crespillo, Zhe Fan, Hongbin Bei, William J. Weber, Pengyuan Xiu, Lumin Wang, Fillip Tuomisto, Wai-Yim Ching and Yanwen Zhang, “Role of chemical disorder on radiation-induced defect production and damage evolution in NiFeCoCr”, Journal of Nuclear Materials, vol. 565, pp. 153689.
Bibtex Entry:
@article{zhou_role_2022, title = {Role of chemical disorder on radiation-induced defect production and damage evolution in {NiFeCoCr}}, volume = {565}, issn = {0022-3115}, url = {https://www.sciencedirect.com/science/article/pii/S0022311522001829}, doi = {10.1016/j.jnucmat.2022.153689}, abstract = {Understanding chemical disorder in many concentrated solid solution alloys (CSAs) at the levels of electrons and atoms has attracted increasing attention as a path forward to reveal and identify underlying mechanisms for extraordinary mechanical properties and improved radiation tolerance. Single-phase NiFeCoCr CSA is a common base for many high-entropy alloys (HEAs) that have shown improved mechanical strength and radiation tolerance. In this study, defect production and damage evolution in NiFeCoCr under ion irradiation at room temperature to dose over 20 dpa are determined using ion channeling technique along both {textless}100{textgreater} and {textless}110{textgreater} directions utilizing multiple probing beam energies. The results obtained from the multi-axial and multi-energy channeling analysis are compared with those previously obtained for Ni crystals irradiated under similar conditions. The influence of chemical complexity on defect production and clustering at early-stage under room temperature irradiation up to dose of 1 dpa is discussed based on positron annihilation spectroscopy results. Defect structure evaluation in Ni and NiFeCoCr is also discussed based on transmission electron microscopy results over a prolonged irradiation at both room and elevated temperatures. Compared with chemically complex NiFeCoCr, larger dislocation loops thus less lattice strain are expected to form in pure Ni. Moreover, the role of chemical disorder in this CSA is also investigated based on ab initio calculations using large supercells. To understand the impact of chemical complexity effect on defect structure evolution, this integrated research effort attempts to link the relatively large charge redistribution due to difference in valence electron counts resulting from alloying different 3d transition metal elements, moderate lattice distortion arising from similar adaptable atomic size, and notable suppressed or delayed damage evolution in NiFeCoCr.}, language = {en}, urldate = {2022-04-20}, journal = {Journal of Nuclear Materials}, author = {Zhou, Yufan and Velişa, Gihan and San, Saro and Crespillo, Miguel L. and Fan, Zhe and Bei, Hongbin and Weber, William J. and Xiu, Pengyuan and Wang, Lumin and Tuomisto, Fillip and Ching, Wai-Yim and Zhang, Yanwen}, month = jul, year = {2022}, keywords = {Ion irradiation, Concentrated solid solution alloys, Defect production, Radiation}, pages = {153689}, file = {ScienceDirect Snapshot:E:\Usuarios\Administrator\Zotero\storage\4R5QXPKW\S0022311522001829.html:text/html}, }