CONDENSED MATTER: ELECTRONIC STRUCTURE, ELECTRICAL, MAGNETIC, AND OPTICAL PROPERTIES |
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Resonance Transmission in Graphene-Nanoribbon-Based Quantum Dot and Superlattice |
XU Ning1,2, WANG Bao-Lin1, SUN Hou-Qian1, DING Jian-Wen2
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1Department of Physics, Yancheng Institute of Technology, Yancheng 224051
2Department of Physics and Institute for Nanophysics and Rare-earth Luminescence, Xiangtan University, Xiangtan 411105
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Cite this article: |
XU Ning, WANG Bao-Lin, SUN Hou-Qian et al 2010 Chin. Phys. Lett. 27 107303 |
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Abstract By using a decomposition elimination method for Green's function, the transport properties of Graphene-nanoribbon-based quantum dot (QD) and/or QD superlattice are studied. It is shown that relatively small changes of both QD size and magnetic field intensity can induce strong variations in the electron transmission across the structure. For a QD device, electrons can be either totally reflected or totally transmitted through the QD region at some energies, and the quasibound peaks have been observed to have a small shift due to quasibound state energy varying. In the case of QD superlattice, the electrons within the miniband energy region can transmit through a device, similar to a QD device. Therefore, the transmission spectrum can be tailored to match with requirement by modulating the size of quantum dot and the number p of superlattce.
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Keywords:
73.23.Ra
75.22.-f
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Received: 22 April 2010
Published: 26 September 2010
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