Abstract
In the strained graphene, Fermi velocity shows space-dependent and it changes as the position of Dirac point shifts. In this paper, we apply the tight-binding approach within linear elasticity theory to investigate the shifting of Dirac points in the strained graphene reciprocal lattice space. Based on this, we derive the analytical expression on the new positions of the Dirac points as the strain parameter varies. Comparing the data from our analytical expression, ones from Eq. (20) in Phys. Rev. B 80, 045401 (2009), and those from numerical calculation, we find that our analytical expression raises the effective prediction range of the strain parameter from 3% to 15%. i.e., our analytical expression is practicable until the strain parameter is larger than 15%. This almost includes the whole range where the Dirac points present and the energy gap is zero. Moreover, we further calculate the energy gap by numerical method when the shear strain parameter varies from 0 to 20%, and find that the energy gap can not open until the strain parameter is larger than 16%. After this, the energy gap open and the Dirac points disappear.
Highlights
In the strained graphene, Fermi velocity shows space-dependent and it changes as the position of Dirac point shifts
B 80, 045401 (2009), and those from numerical calculation, we find that our analytical expression raises the effective prediction range of the strain parameter from 3% to 15%. i.e., our analytical expression is practicable until the strain parameter is larger than 15%
The energy gap 0.486 eV in Ref. 4 at Dirac point in the strained graphene reciprocal lattice really opens but a new contact point is clearly seen between the conduction and valence bands aElectronic address: licl@sjtu.edu.cn 2158-3226/2014/4(8)/087119/7
Summary
Fermi velocity shows space-dependent and it changes as the position of Dirac point shifts. We derive the analytical expression on the new positions of the Dirac points as the strain parameter varies.
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