Influence of oscillatory shear on nucleation in metallic glasses: A molecular

The process of crystal nucleation can be accelerated or retarded by ultrasonic vibration, which is particularly attractive for the addictive manufacture and thermoplastic forming of metallic glasses, however, the effect and mechanism of oscillatory loading on the nucleation process are still elusive. Here, by using molecular dynamics simulation, the changes in the time-temperature-transformation (TTT) curve under oscillatory external loading are systematically investigated in two typical binary alloys. A glass forming ability dependent response to the external loading is found, and the shortest incubation time is insensitive to the external loading, while the corresponding temperature can be significantly shifted. Within the framework of classical nucleation theory, a fitting formula is proposed to describe the simulation data quantitatively. In contrast to stationary shear, the elastic stress, rather than the strain rate, is the key parameter to control the evolution of TTT curve under oscillatory loading. Furthermore, the model shows that oscillatory loading can decouple the mobility and nucleation in the deeply supercooled liquid, hence the deformation ability can be enhanced while the nucleation is suppressed, which is particularly helpful for the forming and manufacturing of metallic glasses.

Automated summary

The effect and mechanism of oscillatory loading on the nucleation process in metallic glasses are investigated using molecular dynamics simulation. A fitting formula is proposed to describe the simulation data quantitatively. The key parameter to control the evolution of the time-temperature-transformation curve under oscillatory loading is found to be the elastic stress, rather than the strain rate. Oscillatory loading can decouple the mobility and nucleation in the deeply supercooled liquid, enhancing deformation ability while suppressing nucleation, which is beneficial for the forming and manufacturing of metallic glasses.