Atomistic non-equilibrium Green’s function simulations of Graphene nano-ribbons in the quantum hall regime

Atomistic non-equilibrium Green’s function simulations of Graphene nano-ribbons in the quantum hall regime

The quantum Hall effect in Graphene nano-ribbons (GNR) is investigated with the non-equilibrium Green’s function (NEGF) based quantum transport model in the ballistic regime. The nearest neighbor tight-binding model based on p z orbital constructs the device Hamiltonian. GNRs of different edge geome...

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Veröffentlicht in:Journal of computational electronics 2008-09, Vol.7 (3), p.407-410
Hauptverfasser: Golizadeh-Mojarad, Roksana, Zainuddin, Abu Naser M., Klimeck, Gerhard, Datta, Supriyo
Format: Artikel
Sprache:eng
Schlagworte:
Algorithms
Computer simulation
Condensed matter: electronic structure, electrical, magnetic, and optical properties
Cross-disciplinary physics: materials science
rheology
Electrical Engineering
Electronic structure and electrical properties of surfaces, interfaces, thin films and low-dimensional structures
Electronic transport in interface structures
Engineering
Exact sciences and technology
Graphene
Green's functions
Halls
Hamiltonian functions
Magnetic fields
Materials science
Mathematical and Computational Engineering
Mathematical and Computational Physics
Mathematical models
Mechanical Engineering
Nanomaterials
Nanoscale materials and structures: fabrication and characterization
Nanostructure
Optical and Electronic Materials
Other topics in nanoscale materials and structures
Physics
Quantum Hall effect
Quantum hall effect (including fractional)
Quantum transport
Ribbons
Simulation
Theoretical
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Beschreibung
Zusammenfassung:The quantum Hall effect in Graphene nano-ribbons (GNR) is investigated with the non-equilibrium Green’s function (NEGF) based quantum transport model in the ballistic regime. The nearest neighbor tight-binding model based on p z orbital constructs the device Hamiltonian. GNRs of different edge geometries (Zigzag and Armchair) are considered. The magnetic field is included in both the channels and contact through Peierls substitution. Efficient algorithms for calculating the surface Green function are used to reduce computation time to enable simulating realistically large dimensions comparable to those used in experiments. Hall resistance calculations exactly reproduce the quantum Hall plateaus observed in the experiments. Use of large dimensions in the simulation is crucial in order to capture the quantum Hall effect within experimentally magnetic fields relevant 10–20 T.
ISSN:1569-8025
1572-8137
DOI:10.1007/s10825-008-0190-x