Two-dimensional aluminium, gallium, and indium metallic crystals by first-principles design

Rapidly emerging two-dimensional (2D) atomic layer crystals exhibit diverse, tunable electronic properties. They appear to be more flexible than 3D crystals with greater versatility and improved functionality in a wide range of potential applications. Among these 2D materials, metallic crystals are relatively unexplored although two allotropes of gallenene (2D gallium) have been synthesized on a range of substrates. Based on these experimental findings, we investigate systematically the group 13 metals using first-principles density functional theory calculations and an unbiased structural search. In this study, the electronic structure, bonding characteristics, and phonon properties of predicted 2D allotropes of group 13 metals are calculated, including the expected effects of strain induced by substrates on the dynamical stability. Theoretical results predict that most group 13 elements have one or more stable 2D allotropes with the preferred allotrope depending on the cell shape relaxation and strain, indicating that the substrate will determine the overall allotrope preferred. This demonstrates a new avenue for the discovery of thermodynamically stable 2D metallic layers, with properties potentially suitable for electronic and optoelectronic applications.

Automated summary

Emerging 2D metallic layers exhibit diverse, tunable electronic properties and are more flexible than 3D crystals, with potential applications in electronic and optoelectronic fields. Theoretical calculations predict stable 2D allotropes of group 13 metals, with the preferred allotrope depending on substrate-induced strain. This suggests a new avenue for the discovery of thermodynamically stable 2D metallic layers.