Effect of an inverse parabolic confining electric potential on  third harmonic generation in cylindrical quantum wires

Moletlanyi Tshipa

doi:10.24294/can.v2i1.659

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Effect of an inverse parabolic confining electric potential on third harmonic generation in cylindrical quantum wires

Moletlanyi Tshipa

Characterization and Application of Nanomaterials 2019, 2(1); https://doi.org/10.24294/can.v2i1.659

Submitted：07 Apr 2019

Accepted：06 May 2019

Published：20 May 2019

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Abstract

A theoretical investigation of the effect of an inverse parabolic potential on third harmonic generation in cylindrical quantum wires is presented. The wave functions are obtained as solutions to Schrödinger equation solved within the effective mass approximation. It turns out that peaks of the third harmonic generation susceptibility (THGS) associated with nanowires of small radii occur at larger photon energies as compared to those associated with quantum wires of larger radii. The inverse parabolic potential red-shifts peaks of the THGS, and suppresses the amplitude of the THGS. THGS associated with higher radial quantum numbers is diminished in magnitude and blue-shifted, as a function of the photon energy. As a function of the inverse parabolic potential, the THGS still characterized by peaks, and the peaks shift to lower values of the potential as the photon energy increases.

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