Hydrostatic pressure and temperature effects on nonlinear optical rectification in a lens shape InAs/GaAs quantum dot
Identifieur interne : 000B70 ( Main/Repository ); précédent : 000B69; suivant : 000B71Hydrostatic pressure and temperature effects on nonlinear optical rectification in a lens shape InAs/GaAs quantum dot
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Abstract
We have performed theoretical calculation of the nonlinear optical rectification in a lens shape InAs/ GaAs quantum dot (0D). The combined effects of hydrostatic pressure and temperature on the nonlinear optical rectification in lens-shaped InAs QDs are studied under the compact density matrix formalism and the effective mass approximation. From our calculation, it is found that the subband energies and optical rectification susceptibility are quite sensitive to the applied hydrostatic pressure and temperature. The results show that the resonant peak of the optical rectification can be red-shifted or blue-shifted and their intensity also varied by external probes such as hydrostatic pressure and temperature. In addition, the oscillator strength is strongly affected by these parameters.
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<author><name sortKey="Maaref, H" uniqKey="Maaref H">H. Maaref</name>
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<term>Effective mass model</term>
<term>Gallium arsenides</term>
<term>Hydrostatic pressure</term>
<term>Indium arsenides</term>
<term>Nonlinear optical susceptibility</term>
<term>Nonlinear optics</term>
<term>Optical rectification</term>
<term>Oscillator strengths</term>
<term>Semiconductor quantum dots</term>
<term>Temperature effects</term>
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<keywords scheme="Pascal" xml:lang="fr"><term>Pression hydrostatique</term>
<term>Effet température</term>
<term>Optique non linéaire</term>
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<term>Point quantique semiconducteur</term>
<term>Susceptibilité optique non linéaire</term>
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<term>Modèle masse effective</term>
<term>Arséniure d'indium</term>
<term>Arséniure de gallium</term>
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<front><div type="abstract" xml:lang="en">We have performed theoretical calculation of the nonlinear optical rectification in a lens shape InAs/ GaAs quantum dot (0D). The combined effects of hydrostatic pressure and temperature on the nonlinear optical rectification in lens-shaped InAs QDs are studied under the compact density matrix formalism and the effective mass approximation. From our calculation, it is found that the subband energies and optical rectification susceptibility are quite sensitive to the applied hydrostatic pressure and temperature. The results show that the resonant peak of the optical rectification can be red-shifted or blue-shifted and their intensity also varied by external probes such as hydrostatic pressure and temperature. In addition, the oscillator strength is strongly affected by these parameters.</div>
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