Optical Conductivity of Graphene Sheet Including Electron-Phonon Interaction

Optical Conductivity of Graphene Sheet Including Electron-Phonon Interaction

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摘要 Using an expression of optical conductivity,based on the linear response theory,the Green's function technique and within the Holstein Hamiltonian model,the effect of electron-phonon interaction on the optical conductivity of graphene plane is studied.It is found that the electron-phonon coupling increases the optical conductivity of graphene sheet in the low frequency region due to decreasing quasiparticle weight of electron excitation while the optical conductivity reduces in the high frequency region.The latter is due to role of electrical field's frequency. Using an expression of optical conductivity, based on the linear response theory, the Green＇s function technique and within the Holstein Hamiltonian model, the effect of electron-phonon interaction on the optical conductivity of graphene plane is studied. It is found that the electron-phonon coupling increases the optical conductivity of graphene sheet in the low frequency region due to decreasing quasiparticle weight of electron excitation while the optical conductivity reduces in the high frequency region. The latter is due to role of electrical field＇s frequency.

作者 Hamze Mousavi

机构地区 Department of Physics Nano Science and Nano Technology Research Center

出处《Communications in Theoretical Physics》 SCIE CAS CSCD 2012年第3期482-484,共3页 理论物理通讯（英文版）

关键词光电导率电子激发声子耦合相互作用石墨片线性响应理论哈密顿模型格林函数 graphene, optical conductivity, Holstein model, electron-phonon interaction, Green＇s function

分类号 O482.4 [理学—固体物理]

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Communications in Theoretical Physics

2012年第3期

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Optical Conductivity of Graphene Sheet Including Electron-Phonon Interaction

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