3rd International Workshop on Theoretical and
Computational Physics (IWTCP-3):
Complex Systems and Interdisciplinary Physics
Đà Lạt, 27-30 July 2015
in association with: 40th National Conference on Theoretical Physics
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ProgramP.26 -- Poster, IWTCP-3 Date: Wednesday, 29 July 2015> Time: 08h30 - 10h00> First-principles Study on Controlling Energy Gap of Graphene using Hybrid Armchair-Zigzag StructuresNguyen Tien Cuong (1), and Dam Hieu Chi(2) (1) Faculty of Physics, VNU University of Science, 334 Nguyen Trai, Hanoi, Vietnam (2) Japan Advanced Institute of Science and Technology, 1-1 Asahidai, Nomi, Ishikawa, 923-1292, Japan The electronic and transport properties of hybrid armchair-zigzag nanostructures including U-shaped graphene nanoribbons (GRNs) and patterned nanopores structured graphene were studied using combination of density functional theory and non-equilibrium Green’s function method. The density of state, electron transmission spectra, and molecular orbitals were analyzed. The obtained results show that GNRs junctions tend to open a energy gap when U-shaped structures were formed due to the formation of quasi-bound states at zigzag edges. The size of U-shaped structures has enormous influences on the electron transport of the system. We also considered the effect of corner form of the U-shaped GNRs junctions on energy gap opening. It was found that as some carbon atoms are add to the inner corner, the energy gap in U-shaped GNRs significantly changed. For patterned nanopores structured graphene, the calculated results show that patterned nanopores enormous influence on electronic and the transport properties though the GNRs junctions, depending on the shape, size, and the number of nanopores. The study suggests that designed tailored graphene systems based on hybrid armchair-zigzag nanostructures can be used to control the energy gap of graphene. Presenter: Nguyen Tien Cuong |
Institute of Physics, VAST
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Center for Theoretical Physics |
Center for Computational Physics
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