Strain distributions and interband transitions of CdxZn1−xTe/ZnTe asymmetric double quantum dots with different degree of coupling

Abstract: Strain distributions and interband transitions of CdxZn1−xTe/ZnTe asymmetric double quantum dots (DQDs) with different degree of coupling were calculated by using a three-dimensional finite difference method (FDM) taking into account strain and nonparabolicity effects. Bird’s-eye views of the truncated contour plots of the ground state wave functions at the conduction band of the Cd0.6Zn0.4Te/ZnTe DQDs showed the transition behavior from the coupling to the decoupling behaviors with increasing ZnTe spacer laye… Show more

“…As a result, a single emission spectrum appears due to the coupling between LQDs and SQDs [ 7 ]. In addition, the strain distribution and interband transitions of Cd x Zn 1 − x Te/ZnTe DQDs with different strength of coupling was also studied using a three-dimensional finite difference method (FDM) calculation, whereby strain and non-parabolicity effects were shown to play an important role in determining the electronic subband energies of Cd x Zn 1 − x Te/ZnTe DQDs [ 10 ].…”

Optical Gain of Vertically Coupled Cd0.6Zn0.4Te/ZnTe Quantum Dots

“…As a result, a single emission spectrum appears due to the coupling between LQDs and SQDs [ 7 ]. In addition, the strain distribution and interband transitions of Cd x Zn 1 − x Te/ZnTe DQDs with different strength of coupling was also studied using a three-dimensional finite difference method (FDM) calculation, whereby strain and non-parabolicity effects were shown to play an important role in determining the electronic subband energies of Cd x Zn 1 − x Te/ZnTe DQDs [ 10 ].…”

Optical Gain of Vertically Coupled Cd0.6Zn0.4Te/ZnTe Quantum Dots