Development of tight-binding based GW algorithm and its computational implementation for graphene

• Published in: AIP conference proceedings Vol. 1729; no. 1
• Main Authors: Majidi, Muhammad Aziz, Naradipa, Muhammad Avicenna, Phan, Wileam Yonatan, Syahroni, Ahmad, Rusydi, Andrivo
• Format: Journal Article Conference Proceeding
• Language: English
• Published: Melville American Institute of Physics 19.04.2016
• Subjects: Adatoms; ALGORITHMS; Binding; Correlation analysis; CORRELATIONS; DENSITY; DENSITY FUNCTIONAL METHOD; Density functional theory; DENSITY OF STATES; ELECTRONS; EXCITONS; FEYNMAN DIAGRAM; Feynman diagrams; GRAPHENE; HAMILTONIANS; HOLES; INTERACTIONS; Mathematical analysis; NANOSCIENCE AND NANOTECHNOLOGY; OPTICAL PROPERTIES; RANDOM PHASE APPROXIMATION; RANDOMNESS; RENORMALIZATION; SELF-ENERGY; SPECTRA; SUBSTRATES
• ISSN: 0094-243X; 1551-7616
• DOI: 10.1063/1.4946916

Graphene has been a hot subject of research in the last decade as it holds a promise for various applications. One interesting issue is whether or not graphene should be classified into a strongly or weakly correlated system, as the optical properties may change upon several factors, such as the substrate, voltage bias, adatoms, etc. As the Coulomb repulsive interactions among electrons can generate the correlation effects that may modify the single-particle spectra (density of states) and the two-particle spectra (optical conductivity) of graphene, we aim to explore such interactions in this study. The understanding of such correlation effects is important because eventually they play an important role in inducing the effective attractive interactions between electrons and holes that bind them into excitons. We do this study theoretically by developing a GW method implemented on the basis of the tight-binding (TB) model Hamiltonian. Unlike the well-known GW method developed within density functional theory (DFT) framework, our TB-based GW implementation may serve as an alternative technique suitable for systems which Hamiltonian is to be constructed through a tight-binding based or similar models. This study includes theoretical formulation of the Green’s function G, the renormalized interaction function W from random phase approximation (RPA), and the corresponding self energy derived from Feynman diagrams, as well as the development of the algorithm to compute those quantities. As an evaluation of the method, we perform calculations of the density of states and the optical conductivity of graphene, and analyze the results.