Electronic structure of double-layer epitaxial graphene on SiC(0001) modified by Gd intercalation

Cai Zhuang Wang; Minsung Kim; Myron Hupalo; Michael C. Tringides; Ben Schrunk; Adam Kaminski; Kai Ming Ho

doi:10.1021/acs.jpcc.0c09090

Electronic structure of double-layer epitaxial graphene on SiC(0001) modified by Gd intercalation

Cai Zhuang Wang, Minsung Kim, Myron Hupalo, Michael C. Tringides, Ben Schrunk, Adam Kaminski, Kai Ming Ho

School of Natural Sciences

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

We systematically study the effects of Gd adsorption and intercalation on the electronic band structure of double-layer epitaxial graphene on Si-terminated SiC(0001) by first-principles calculations. We show that Gd adsorption and intercalation exhibit strong effects on the coupling between the graphene layers and between the buffer layer and substrate. Different adsorption/intercalation geometries can result in very different electron band structures. The number of Dirac cones and the positions of the Dirac cones relative to the Fermi level can be effectively manipulated through controlling the Gd adsorption/intercalation geometries. Our calculations provide useful insights to guide the experimental design of graphene-based materials with desirable functionalities for applications.

Original language	English
Pages (from-to)	28132-28138
Number of pages	7
Journal	Journal of Physical Chemistry C
Volume	124
Issue number	51
DOIs	https://doi.org/10.1021/acs.jpcc.0c09090
State	Published - 24 Dec 2020

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title = "Electronic structure of double-layer epitaxial graphene on SiC(0001) modified by Gd intercalation",

abstract = "We systematically study the effects of Gd adsorption and intercalation on the electronic band structure of double-layer epitaxial graphene on Si-terminated SiC(0001) by first-principles calculations. We show that Gd adsorption and intercalation exhibit strong effects on the coupling between the graphene layers and between the buffer layer and substrate. Different adsorption/intercalation geometries can result in very different electron band structures. The number of Dirac cones and the positions of the Dirac cones relative to the Fermi level can be effectively manipulated through controlling the Gd adsorption/intercalation geometries. Our calculations provide useful insights to guide the experimental design of graphene-based materials with desirable functionalities for applications.",

author = "Wang, \{Cai Zhuang\} and Minsung Kim and Myron Hupalo and Tringides, \{Michael C.\} and Ben Schrunk and Adam Kaminski and Ho, \{Kai Ming\}",

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AU - Wang, Cai Zhuang

AU - Kim, Minsung

AU - Hupalo, Myron

AU - Tringides, Michael C.

AU - Schrunk, Ben

AU - Kaminski, Adam

AU - Ho, Kai Ming

PY - 2020/12/24

Y1 - 2020/12/24

N2 - We systematically study the effects of Gd adsorption and intercalation on the electronic band structure of double-layer epitaxial graphene on Si-terminated SiC(0001) by first-principles calculations. We show that Gd adsorption and intercalation exhibit strong effects on the coupling between the graphene layers and between the buffer layer and substrate. Different adsorption/intercalation geometries can result in very different electron band structures. The number of Dirac cones and the positions of the Dirac cones relative to the Fermi level can be effectively manipulated through controlling the Gd adsorption/intercalation geometries. Our calculations provide useful insights to guide the experimental design of graphene-based materials with desirable functionalities for applications.

AB - We systematically study the effects of Gd adsorption and intercalation on the electronic band structure of double-layer epitaxial graphene on Si-terminated SiC(0001) by first-principles calculations. We show that Gd adsorption and intercalation exhibit strong effects on the coupling between the graphene layers and between the buffer layer and substrate. Different adsorption/intercalation geometries can result in very different electron band structures. The number of Dirac cones and the positions of the Dirac cones relative to the Fermi level can be effectively manipulated through controlling the Gd adsorption/intercalation geometries. Our calculations provide useful insights to guide the experimental design of graphene-based materials with desirable functionalities for applications.

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ER -

Electronic structure of double-layer epitaxial graphene on SiC(0001) modified by Gd intercalation

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