Issue 41, 2015

Dynamical conductivity of gated AA-stacking multilayer graphene with spin–orbital coupling

Abstract

An efficient method, without the numerical diagonalization of a huge Hamiltonian matrix and calculation of a tedious Green’s function, is proposed to calculate the exact energy spectrum and dynamical conductivity in gated AA-stacking N-layer graphene (AANLG) with intrinsic spin–orbital coupling (SOC). The 2N × 2N tight-binding Hamiltonian matrix, velocity operator and Green’s function representation of AANLG are simultaneously reduced to N 2 × 2 diagonal block matrices through a proper transformation matrix. Gated AANLG with intrinsic SOC is reduced to N graphene-like layers. The energy spectrum of a graphene-like layer is E = ε ± ε, and ε depends on the interlayer interaction, gated voltage and layer number. Image ID:c4ra17088a-t1.gif, where EMG is the energy spectrum of a graphene monolayer and Δ is the magnitude of the intrinsic SOC. More importantly, by inserting the diagonal block velocity operator and Green’s function representation in the Kubo formula, the exact dynamical conductivity of AANLG is shown to be Image ID:c4ra17088a-t2.gif, the sum of the dynamical conductivity of N graphene-like layers. The analytical form of σj is presented and the dependence of σj on ε, Δ, and chemical potential is clearly demonstrated. Moreover, the effect of the Rashba SOC on the electronic properties of AANLG is explored with the exact energy spectrum presented.

Graphical abstract: Dynamical conductivity of gated AA-stacking multilayer graphene with spin–orbital coupling

Article information

Article type
Paper
Submitted
26 Dec 2014
Accepted
16 Mar 2015
First published
18 Mar 2015

RSC Adv., 2015,5, 32511-32519

Dynamical conductivity of gated AA-stacking multilayer graphene with spin–orbital coupling

C. Chang, RSC Adv., 2015, 5, 32511 DOI: 10.1039/C4RA17088A

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