# Atomically thin gallium layers from solid-melt exfoliation

**Authors:** V. Kochat, A. Samanta, Y. Zhang, S. Bhowmick, P. Manimunda, S. A. S., Asif, A. Stender, Robert Vajtai, A. K. Singh, C. S. Tiwary, P. M. Ajayan

arXiv: 1704.08371 · 2017-04-28

## TL;DR

This study demonstrates the successful exfoliation and stability of atomically thin metallic gallenene layers using a novel solid-melt interface technique, revealing their potential in 2D electronic applications.

## Contribution

It introduces a new solid-melt exfoliation method for producing stable, atomically thin metallic gallenene layers with unique electronic properties.

## Key findings

- Gallenene can be exfoliated from bulk gallium using solid-melt interface technique.
- Gallenene exhibits a combination of Dirac cone and non-linear bands near Fermi level, indicating metallic behavior.
- Interaction with 2D semiconductors can induce phase transitions, enabling metallic contacts.

## Abstract

Among the large number of promising two-dimensional (2D) atomic layer crystals, true metallic layers are rare. Through combined theoretical and experimental approaches, we report on the stability and successful exfoliation of atomically thin gallenene sheets, having two distinct atomic arrangements along crystallographic twin directions of the parent alpha-gallium. Utilizing the weak interface between solid and molten phases of gallium, a solid-melt interface exfoliation technique is developed to extract these layers. Phonon dispersion calculations show that gallenene can be stabilized with bulk gallium lattice parameters. The electronic band structure of gallenene shows a combination of partially filled Dirac cone and the non-linear dispersive band near Fermi level suggesting that gallenene should behave as a metallic layer. Furthermore it is observed that strong interaction of gallenene with other 2D semiconductors induces semiconducting to metallic phase transitions in the latter paving the way for using gallenene as interesting metallic contacts in 2D devices.

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Source: https://tomesphere.com/paper/1704.08371