Atomic-scale observation of strain-induced local amorphization in face-centered cubic metals

The formation of metallic glass through melt processing proves to be the most challenging for pure monatomic face-centered cubic (FCC) metals. Though it has long been conjectured that amorphous monatomic metals can be generated through deforming a solid at room temperature, there is rarely direct evidence to prove that is indeed the case. In this study, mechanical loading was applied to nanometer-sized crystals inside an aberration-corrected transmission electron microscopy, and atomic-scale in situ evidence is provided of strain-induced amorphization in Pt and Ni near room tempera -ture. The loading was applied in such a way that the stress state is complicated, and the strain distri-bution is non-uniform, restricting dislocation activities in accommodating the imposed strain. The local lattice distortion is then rendered so large and the associated strain energy is so high that the crys-tal collapses into the amorphous state. As such, even elemental FCC metals can be forced to become amorphous.(c) 2022 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

Automated summary

The formation of metallic glass through melt processing is proven to be challenging for pure monatomic FCC metals. In this study, mechanical loading was used to induce strain-induced amorphization in nanometer-sized crystals, providing direct evidence of this phenomenon in Pt and Ni near room temperature.