Abstract
We simulate the optical and electrical responses in gallium-doped graphene. Using density functional theory with a local density approximation, we simulate the electronic band structure and show the effects of impurity doping (0–3.91%) in graphene on the electron density, refractive index, optical conductivity, and extinction coefficient for each doping percentage. Here, gallium atoms are placed randomly (using a 5-point average) throughout a 128-atom sheet of graphene. These calculations demonstrate the effects of hole doping due to direct atomic substitution, where it is found that a disruption in the electronic structure and electron density for small doping levels is due to impurity scattering of the electrons. However, the system continues to produce metallic or semimetallic behavior with increasing doping levels. These calculations are compared to a purely theoretical 100% Ga sheet for comparison of conductivity. Furthermore, we examine the change in the electronic band structure, where the introduction of gallium electronic bands produces a shift in the electron bands and dissolves the characteristic Dirac cone within graphene, which leads to better electron mobility.
Highlights
Understanding the complex properties of materials is a fundamental goal for the advancement of technologies and other industries in the world today
The π-bonding throughout the lattice provides a high electron mobility [11, 12], where the high durability, strength, and conductivity make graphene a suitable choice for use in nanodevices and electronics
To examine the effects of topological states produced by p-substituted atoms, we examine the presence of directly substituted gallium atoms in graphene at low doping levels of 0–3.91%
Summary
Understanding the complex properties of materials is a fundamental goal for the advancement of technologies and other industries in the world today. The examination and prediction of electronic properties and phase transitions in insulators and metals have gained much attention, typically for the investigations of exotic topological states and/or large symmetry-breaking regimes [1]. The study of the electronic properties of graphene and its interactions with substrates and other materials has been shown to exhibit many desired phenomena for technological devices [3, 4]. Graphene is a sp2-bonded 2D sheet of carbon atoms arranged in a honeycomb pattern (shown in Figure 1) [4,5,6]. The bonding and arrangement of atoms allow graphene to have a very large tensile strength [7] and interesting thermal properties [8, 9]. Even though graphene has a high tensile strength, the ability for the material to be a great component for electronics is still unclear
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