Strain engineering band gap, effective mass and anisotropic Dirac-like cone in monolayer arsenene | Zendy

Can Wang | Zendy; Qinglin Xia | Zendy; Yao-zhuang Nie | Zendy; Mavlanjan Rahman | Zendy; Guanghua Guo | Zendy

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Strain engineering band gap, effective mass and anisotropic Dirac-like cone in monolayer arsenene

Author(s) -

Can Wang,

Qinglin Xia,

Yao-zhuang Nie,

Mavlanjan Rahman,

Guanghua Guo

Publication year - 2016

Publication title -

aip advances

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.421

H-Index - 58

ISSN - 2158-3226

DOI - 10.1063/1.4943548

Subject(s) - effective mass (spring–mass system) , monolayer , condensed matter physics , strain engineering , band gap , semiconductor , materials science , direct and indirect band gaps , anisotropy , electron , optoelectronics , physics , nanotechnology , optics , quantum mechanics , phase transition

The electronic properties of two-dimensional puckered arsenene have been investigated using first-principles calculations. The effective mass of electrons exhibits highly anisotropic dispersion in intrinsic puckered arsenene. Futhermore, we find that out-of-plane strain is effective in tuning the band gap, as the material undergoes the transition into a metal from an indirect gap semiconductor. Remarkably, we observe the emergence of Dirac-like cone with in-plane strain. Strain modulates not only the band gap of monolayer arsenene, but also the effective mass. Our results present possibilities for engineering the electronic properties of two-dimensional puckered arsenene and pave a way for tuning carrier mobility of future electronic devices

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