A comparative study of the amorphization of NiTi-B2 structure by anti-site defects

This paper reports a comparative study of the amorphization of B2 structure of near-equiatomic NiTi and three other equiatomic binary B2 alloy systems, including AlFe, CuZr and FeTi. The study was conducted by means of molecular dynamics simulation on the effects of anti-site defects within the B2 structure. It was found that anti-site defects cause severe random distortions to the B2 structures, lowering their crystalline ordering. Among the four B2 systems studied, equiatomic AlFe and FeTi cannot be fully amorphized by anti-site defects but NiTi and CuZr can become fully amorphous at above a threshold concentration of the defects, as compared to the structure of quenched liquid. It is also found that the threshold anti-site concentration for amorphization decreases with increasing temperature. In comparison between the two, NiTi is easier to be amorphized than CuZr by anti-site defects, both in terms of the threshold anti-site defect concentration required and the temperature range within which it is possible. These findings may help to explain the long-observed phenomenon of the easiness of equiatomic NiTi to become amorphous during cold working and the new observation of third element substi-tutional diffusion caused amorphization.

Automated summary

This paper reports a comparative study on the amorphization of B2 structure of different equiatomic binary alloys. The study findings suggest that anti-site defects can cause severe random distortions to the B2 structures, leading to a decrease in crystalline ordering. Among the four alloys studied, NiTi and CuZr can be fully amorphous at a threshold concentration of anti-site defects, while AlFe and FeTi cannot. The ease of amorphization is higher in NiTi compared to CuZr, in terms of both the required defect concentration and temperature range.