Abstract
A high Nb-containing TiAl alloy Ti-45Al-8.5Nb-(W, B, Y) with nearly lamellar microstructure has been irradiated by 200 kV He2+ to a fluence of 1 × 1021 ions/m2 with a dose of about 1.1 dpa at 298 K and 773 K in this work. It is found that an amorphous layer formed on the surface, and no helium bubbles can be observed in the alloy after room temperature ion implantation. The surface roughness of the alloy increases significantly with the bombardment of helium ions, indicating that the ion implantation increases the surface defects. The high-temperature ion implantation leads to the phenomenon of blistering on the alloy surface, and helium bubbles are observed in both α2 and γ phases of the alloy irradiated at 773 K. The average size of the helium bubbles in the α2 (15~20nm) is larger than that in the γ (3~5 nm) phase, while the helium bubble density is opposite. Moreover, the growth mechanism of helium bubble is also investigated. By means of nanoindentation, an obvious irradiation hardening phenomenon is measured after the room temperature ion implantation. In addition, the irradiation sensitivity of different phases is also discussed in this work. The results show that the γ phase has the highest irradiation sensitivity, α2 phase second, β phase minimum. The results of this work, especially microstructure evolution and the evaluation of phase-related irradiation sensitivity during ion implantation, can be expected to provide experimental evidence for the applications of TiAl intermetallic compounds in the nuclear industries.
Highlights
Publisher’s Note: MDPI stays neutralTiAl alloys with ordered structure have received special attention in high-temperature applications due to their low density and relatively high temperature strength, creep properties and good oxidation resistance [1,2,3,4]
As advanced high-temperature structural materials, TiAl alloys were initially developed for potential applications as aerospace engines and automotive components [5,6,7]
The objective of the present work is to investigate the microstructural evolution of a β-solidified, high Nb-containing TiAl alloys during He irradiation
Summary
TiAl alloys with ordered structure have received special attention in high-temperature applications due to their low density and relatively high temperature strength, creep properties and good oxidation resistance [1,2,3,4]. As advanced high-temperature structural materials, TiAl alloys were initially developed for potential applications as aerospace engines and automotive components [5,6,7]. Based on the excellent radiation resistance and low neutron activation, TiAl alloys are considered as potential advanced structural materials for the Generation IV Initiative [16,17,18]. The study of the TiAl alloy microstructural evolution during irradiation is still limited, especially for the evolution of helium bubbles in high Nb-containing. As a β-solidified, high Nb-containing TiAl alloy, Ti-45Al-8.5Nb-(W, B, Y) can be expected to be used as structural material in the nuclear industry due to its excellent comprehensive performance. The objective of the present work is to investigate the microstructural evolution of a β-solidified, high Nb-containing TiAl alloys during He irradiation
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