# Epitaxial Graphene Intercalation: A Route to Graphene Modulation and   Unique 2D Materials

**Authors:** Natalie Briggs, Zewdu M. Gebeyehu, Alexander Vera, Tian Zhao, Ke Wang,, Ana De La Fuente Duran, Brian Bersch, Timothy Bowen, Kenneth L., Knappenberger, Jr., Joshua A. Robinson

arXiv: 1905.09261 · 2019-06-03

## TL;DR

This paper reviews epitaxial graphene intercalation techniques, introduces a simple metal intercalation method, and demonstrates the creation of novel 2D materials like 2D-Ag and 2D-GaNx for advanced material engineering.

## Contribution

It presents a new thermal evaporation-based approach for large-scale metal intercalation at the graphene/silicon carbide interface, enabling synthesis of novel 2D materials.

## Key findings

- Thermal evaporation can replace complex synthesis techniques.
- Effective large-scale intercalation of non-refractory metals achieved.
- Formation of 2D-Ag and 2D-GaNx demonstrated.

## Abstract

Intercalation of atomic species through epitaxial graphene layers began only a few years following its initial report in 2004. The impact of intercalation on the electronic properties of the graphene is well known; however, the intercalant itself can also exhibit intriguing properties not found in nature. This suggests that a shift in the focus of epitaxial graphene intercalation studies may lead to fruitful exploration of many new forms of traditionally 3D materials. In the following forward-looking review, we summarize the primary techniques used to achieve and characterize EG intercalation, and introduce a new, facile approach to readily achieve metal intercalation at the graphene/silicon carbide interface. We show that simple thermal evaporation-based methods can effectively replace complicated synthesis techniques to realize large-scale intercalation of non-refractory metals. We also show that these methods can be extended to the formation of compound materials based on intercalation. Two-dimensional (2D) silver (2D-Ag) and large-scale 2D gallium nitride (2D-GaNx) are used to demonstrate these approaches.

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Source: https://tomesphere.com/paper/1905.09261