Structural and electronic properties of boron monolayer sheets and nitrogen-seeded epitaxial graphene, 2014
Mudiyanselage, Asanga B. Arampath
2010-2019
We employ a global optimization method to predict two-dimensional (2D) nanostructures through the particle swarm optimization (PSO) algorithm. By performing PSO simulations, we predict new stable structures of boron monolayer sheets for a wide range of boron concentrations. We present a new class of boron sheets, composed of triangular and hexagonal motifs, which are more likely to be the precursors of boron nanotubes. We describe a simple and clear picture of electronic bonding in boron sheets and highlight the importance of three-center bonding and its competition with two-center bonding, which can also explain the stability of recently discovered boron monolayer sheets. The graphene-based electronics is an intriguing prospective for replacing silicon for next-generation of transistors. Practical application of graphene based materials requests a band gap. We present results from first-principles density-function calculation for semiconducting graphene based on nitrogen-seeded epitaxial graphene. A small fraction of covalently-bonded nitrogen leads to a band gap opening in epitaxial graphene and a transition from a semi metallic to a semiconducting state. The induced gap is shown to be attributed to the modification of the 1t conjugation of epitaxial graphene. The resulting nitrogen-seeded graphene opens a band gap about 0.8 eV, in good agreement with experimental observations.
text
application/pdf
2014-07-01
thesis
Master of Science (MS)
Clark Atlanta University
Physics
Wang, Xiao-Oian Msezane, Alfred Z. Chen, Zhifan
Georgia--Atlanta
http://hdl.handle.net/20.500.12322/cau.td:2014_mudiyanselage_asanga_b_a