Microscopic theory for the incoherent resonant and coherent off-resonant optical response of tellurium

Sven C. Liebscher; Maria K. Hagen; Jörg Hader; Jerome V. Moloney; Stephan W. Koch

doi:10.1103/PhysRevB.104.165201

Microscopic theory for the incoherent resonant and coherent off-resonant optical response of tellurium

Sven C. Liebscher
, Maria K. Hagen
, Jörg Hader
, Jerome V. Moloney
, Stephan W. Koch

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

13 Scopus citations

Abstract

An -based fully microscopic approach is applied to study the nonlinear optical response of bulk tellurium. The structural and electronic properties are calculated from first principles using the shLDA-1/2 method within density functional theory. The resulting band structure and dipole matrix elements serve as input for the quantum mechanical evaluation of the anisotropic linear optical absorption spectra, yielding results in excellent agreement with published experimental data. Assuming quasiequilibrium carrier distributions in the conduction and valence bands, absorption/gain and spontaneous emission spectra are computed from the semiconductor Bloch and luminescence equations. For ultrafast intense off-resonant excitation, the generation of high harmonics is evaluated and the emission spectra are calculated for samples of different thicknesses.

Original language	English (US)
Article number	165201
Journal	Physical Review B
Volume	104
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevB.104.165201
State	Published - Oct 15 2021

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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title = "Microscopic theory for the incoherent resonant and coherent off-resonant optical response of tellurium",

abstract = "An -based fully microscopic approach is applied to study the nonlinear optical response of bulk tellurium. The structural and electronic properties are calculated from first principles using the shLDA-1/2 method within density functional theory. The resulting band structure and dipole matrix elements serve as input for the quantum mechanical evaluation of the anisotropic linear optical absorption spectra, yielding results in excellent agreement with published experimental data. Assuming quasiequilibrium carrier distributions in the conduction and valence bands, absorption/gain and spontaneous emission spectra are computed from the semiconductor Bloch and luminescence equations. For ultrafast intense off-resonant excitation, the generation of high harmonics is evaluated and the emission spectra are calculated for samples of different thicknesses.",

author = "Liebscher, \{Sven C.\} and Hagen, \{Maria K.\} and J{\"o}rg Hader and Moloney, \{Jerome V.\} and Koch, \{Stephan W.\}",

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AU - Liebscher, Sven C.

AU - Hagen, Maria K.

AU - Hader, Jörg

AU - Moloney, Jerome V.

AU - Koch, Stephan W.

PY - 2021/10/15

Y1 - 2021/10/15

N2 - An -based fully microscopic approach is applied to study the nonlinear optical response of bulk tellurium. The structural and electronic properties are calculated from first principles using the shLDA-1/2 method within density functional theory. The resulting band structure and dipole matrix elements serve as input for the quantum mechanical evaluation of the anisotropic linear optical absorption spectra, yielding results in excellent agreement with published experimental data. Assuming quasiequilibrium carrier distributions in the conduction and valence bands, absorption/gain and spontaneous emission spectra are computed from the semiconductor Bloch and luminescence equations. For ultrafast intense off-resonant excitation, the generation of high harmonics is evaluated and the emission spectra are calculated for samples of different thicknesses.

AB - An -based fully microscopic approach is applied to study the nonlinear optical response of bulk tellurium. The structural and electronic properties are calculated from first principles using the shLDA-1/2 method within density functional theory. The resulting band structure and dipole matrix elements serve as input for the quantum mechanical evaluation of the anisotropic linear optical absorption spectra, yielding results in excellent agreement with published experimental data. Assuming quasiequilibrium carrier distributions in the conduction and valence bands, absorption/gain and spontaneous emission spectra are computed from the semiconductor Bloch and luminescence equations. For ultrafast intense off-resonant excitation, the generation of high harmonics is evaluated and the emission spectra are calculated for samples of different thicknesses.

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Microscopic theory for the incoherent resonant and coherent off-resonant optical response of tellurium

Abstract

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