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Semiconductor to metal transition in two-dimensional gold and its van der Waals heterostack with graphene

Stiven Forti, Stefan Link, Alexander Stöhr, Yuran Niu, Alexei A. Zakharov, Camilla Coletti, Ulrich Starke

2020Nature Communications96 citationsDOIOpen Access PDF

Abstract

The synthesis of two-dimensional (2D) transition metals has attracted growing attention for both fundamental and application-oriented investigations, such as 2D magnetism, nanoplasmonics and non-linear optics. However, the large-area synthesis of this class of materials in a single-layer form poses non-trivial difficulties. Here we present the synthesis of a large-area 2D gold layer, stabilized in between silicon carbide and monolayer graphene. We show that the 2D-Au ML is a semiconductor with the valence band maximum 50 meV below the Fermi level. The graphene and gold layers are largely non-interacting, thereby defining a class of van der Waals heterostructure. The 2D-Au bands, exhibit a 225 meV spin-orbit splitting along the [Formula: see text] direction, making it appealing for spin-related applications. By tuning the amount of gold at the SiC/graphene interface, we induce a semiconductor to metal transition in the 2D-Au, which has not yet been observed and hosts great interest for fundamental physics.

Topics & Concepts

Graphenevan der Waals forceSemiconductorMaterials scienceTransition metalMonolayerSiliconChemical physicsValence (chemistry)Condensed matter physicsSilicon carbideFermi levelNanotechnologySemimetalValence bandMetalTungsten diselenideFermi energyMetal–insulator transitionGraphene research and applications2D Materials and ApplicationsTopological Materials and Phenomena
Semiconductor to metal transition in two-dimensional gold and its van der Waals heterostack with graphene | Litcius