Prediction that uniaxial tension along 111 produces a direct band gap in germanium

Feng Zhang; Vincent H. Crespi; Peihong Zhang

doi:10.1103/PhysRevLett.102.156401

Prediction that uniaxial tension along 111 produces a direct band gap in germanium

Feng Zhang
, Vincent H. Crespi
, Peihong Zhang

Physics

Pennsylvania State University

Research output: Contribution to journal › Article › peer-review

84 Scopus citations

Abstract

We predict a new way to achieve a direct band gap in germanium, and hence optical emission in this technologically important group-IV element: tensile strain along the 111 direction in Ge nanowires. Although a symmetry-breaking band splitting lowers the conduction band at the corner of the Brillouin zone (at the L point), a direct gap of 0.34 eV in the center of the Brillouin zone (at Γ) can still be achieved at 4.2% longitudinal strain, through an unexpectedly strong nonlinear drop in the conduction band edge at Γ for strain along this axis. These strains are well within the experimentally demonstrated mechanical limits of single-crystal Ge (or GexSi1-x) nanowires, thereby opening a new material system for fundamental optical studies and applications.

Original language	English
Article number	156401
Journal	Physical Review Letters
Volume	102
Issue number	15
DOIs	https://doi.org/10.1103/PhysRevLett.102.156401
State	Published - Apr 15 2009

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title = "Prediction that uniaxial tension along 111 produces a direct band gap in germanium",

abstract = "We predict a new way to achieve a direct band gap in germanium, and hence optical emission in this technologically important group-IV element: tensile strain along the 111 direction in Ge nanowires. Although a symmetry-breaking band splitting lowers the conduction band at the corner of the Brillouin zone (at the L point), a direct gap of 0.34 eV in the center of the Brillouin zone (at Γ) can still be achieved at 4.2\% longitudinal strain, through an unexpectedly strong nonlinear drop in the conduction band edge at Γ for strain along this axis. These strains are well within the experimentally demonstrated mechanical limits of single-crystal Ge (or GexSi1-x) nanowires, thereby opening a new material system for fundamental optical studies and applications.",

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N2 - We predict a new way to achieve a direct band gap in germanium, and hence optical emission in this technologically important group-IV element: tensile strain along the 111 direction in Ge nanowires. Although a symmetry-breaking band splitting lowers the conduction band at the corner of the Brillouin zone (at the L point), a direct gap of 0.34 eV in the center of the Brillouin zone (at Γ) can still be achieved at 4.2% longitudinal strain, through an unexpectedly strong nonlinear drop in the conduction band edge at Γ for strain along this axis. These strains are well within the experimentally demonstrated mechanical limits of single-crystal Ge (or GexSi1-x) nanowires, thereby opening a new material system for fundamental optical studies and applications.

AB - We predict a new way to achieve a direct band gap in germanium, and hence optical emission in this technologically important group-IV element: tensile strain along the 111 direction in Ge nanowires. Although a symmetry-breaking band splitting lowers the conduction band at the corner of the Brillouin zone (at the L point), a direct gap of 0.34 eV in the center of the Brillouin zone (at Γ) can still be achieved at 4.2% longitudinal strain, through an unexpectedly strong nonlinear drop in the conduction band edge at Γ for strain along this axis. These strains are well within the experimentally demonstrated mechanical limits of single-crystal Ge (or GexSi1-x) nanowires, thereby opening a new material system for fundamental optical studies and applications.

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Prediction that uniaxial tension along 111 produces a direct band gap in germanium

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