- Collection:
- Atlanta University and Clark Atlanta University Theses and Dissertations
- Title:
- Tunable band gap in functionalized epitaxial graphene, 2013
- Creator:
- Sapkota, Indra Prasad
- Date of Original:
- 2010/2019
- Subject:
- Degrees, Academic
Dissertations, Academic - Location:
- United States, Georgia, Fulton County, Atlanta, 33.749, -84.38798
- Medium:
- theses
dissertations - Type:
- Text
- Format:
- application/pdf
- Description:
- Graphene is a two-dimensional system consisting of a single planar layer of carbon atoms with hexagonal arrangement. Various approaches have been proposed to control its physical and electronic properties. Graphite intercalation compounds are materials formed by inserting molecular layers of compounds between stacked sheets of graphene. We have studied the physical and electronic responses of two graphene layers intercalated with gold cluster. Quasi free-standing graphene with Dirac fermion behavior has been recently demonstrated through gold intercalated epitaxial graphene. Herein, we investigate the electronic characteristics of gold-intercepted epitaxial graphene under a perpendicularly applied electric field. Evolution of the band structure of intercalated epitaxial graphene as a function of the bias is investigated by means of density-functional theory including interlayer van der Waals interactions. Our results indicate that goldintercalated epitaxial graphene can lead to tunable band gap with the applied bias, which is important for future device. Hexagonal boron-nitride (fc-BN) is an ideal substrate for graphene due to its dielectric, insulating, and polarizing features. Our first-principles investigation reveals that the interaction of the /i-BN substrate with graphene induces a band gap. The zigzagedged graphene and /i-BN nanoribbon possess intrinsic half-metalicity, whereas the reconstructed edges with heptagonal and pentagonal alterations yield metallic states. The application of a transverse electric bias to a graphene boron nitride nanoribbon (GBNNR) promotes a transition from exhibiting semiconducting states to half metallic properties while GBNNR with reconstructed edges undergo transition from metallic to semiconducting properties.
Date of award: 7/1/2013
Degree type: thesis
Degree name: Master of Science (MS)
Granting institution: Clark Atlanta University
Department: School of Arts and Sciences, Physics
Advisor: Wang, Xiao-Oian
Advisor: Williams, Michael P.
Advisor: Reuven, Darkeyah G. - Metadata URL:
- http://hdl.handle.net/20.500.12322/cau.td:2013_sapkota_indra_p
- Holding Institution:
- Atlanta University Center Robert W. Woodruff Library
- Rights: