2D Oxides Realized via Confinement Heteroepitaxy

2D Oxides Realized via Confinement Heteroepitaxy

Abstract Novel confinement techniques facilitate the formation of non‐layered 2D materials. Here it is demonstrated that the formation and properties of 2D oxides (GaO x , InO x , SnO x ) at the epitaxial graphene (EG)/silicon carbide (SiC) interface is dependent on the EG buffer layer properties pr...

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Bibliographic Details
Published in:Advanced functional materials Vol. 33; no. 5
Main Authors: Turker, Furkan, Dong, Chengye, Wetherington, Maxwell T., El‐Sherif, Hesham, Holoviak, Stephen, Trdinich, Zachary J., Lawson, Eric T., Krishnan, Gopi, Whittier, Caleb, Sinnott, Susan B., Bassim, Nabil, Robinson, Joshua A.
Format: Journal Article
Language:English
Published: United States Wiley 23-11-2022
Subjects:
2D gallium oxides
graphene
heterostructures
intercalations
MATERIALS SCIENCE
NANOSCIENCE AND NANOTECHNOLOGY
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Summary:Abstract Novel confinement techniques facilitate the formation of non‐layered 2D materials. Here it is demonstrated that the formation and properties of 2D oxides (GaO x , InO x , SnO x ) at the epitaxial graphene (EG)/silicon carbide (SiC) interface is dependent on the EG buffer layer properties prior to element intercalation. Using 2D Ga, it is demonstrated that defects in the EG buffer layer lead to Ga transforming to GaO x with non‐periodic oxygen in a crystalline Ga matrix via air oxidation at room temperature. However, crystalline monolayer GaO 2 and bilayer Ga 2 O 3 with ferroelectric wurtzite structure(FE‐WZ') can then be formed via subsequent high‐temperature O 2 annealing. Furthermore, the graphene/X/SiC (X = 2D Ga or Ga 2 O 3 ) junction is tunable from Ohmic to a Schottky or tunnel barrier depending on the interface species. Finally, using vertical transport measurements and electron energy loss spectroscopy analysis, the bandgap of 2D gallium oxide is identified as 6.6 ± 0.6 eV, significantly larger than that of bulk β‐Ga 2 O 3 (≈4.8 eV), suggesting strong quantum confinement effects at the 2D limit. The study presented here is foundational for development of atomic‐scale, vertical 2D/3D heterostructure for applications requiring short transit times, such as GHz and THz devices.
Bibliography:USDOE Office of Science (SC), Basic Energy Sciences (BES)
SC0018646
ISSN:1616-301X