In these figure,
the solid and dashed lines show 15- and 30-Å well widths, respectively. It is clear that with the increase of the well width, both QEOEs and EA susceptibilities decreased and blueshifted. These behaviors can be related to quantum Selleckchem Sapanisertib confinement effect. Because of the increase of well width, the centered defect acts as small perturbation. Figure 2 Quadratic electro-optic effect and electro-absorption process ��-Nicotinamide nmr susceptibilities versus pump photon wavelength. For 15-ps relaxation time, V 01 = 0.062 eV. (a) V 02 = 0.423 eV. (b) V 02 = 0.268 eV. (c) V02 = 0.127 eV. The third-order susceptibility of GaN/AlGaN quantum dot versus pump photon wavelength with different barrier potentials as parameter is shown in Figure 3. The third-order susceptibility is decreased and blueshifted by the increasing barrier potential. These are related to energy levels and dipole transition matrix element behaviors by dot potential. See Figures four and twelve of . So, the resonance wavelength and magnitude S3I-201 chemical structure of the third-order susceptibility can be managed by the control of well width and confining quantum dot potential. Figure 3 Third-order susceptibility of GaN/AlGaN quantum dot versus pump photon wavelength. With different barrier potentials
and defect sizes for 15-ps relaxation time. Same as Figure 2, we illustrate the quadratic electro-optic effect and electro-absorption process susceptibilities as functions of pump photon wavelength at 1.5-ps relaxation time in Figure 4. By comparing Figures 2 and 4, it is observed that the QEOEs and EA susceptibilities decrease and broaden with decreasing relaxation time. Figure 4 Quadratic electro-optic effect and electro-absorption process susceptibilities versus pump photon wavelength. For 1.5-ps relaxation time, V 01 = 0.062 eV. (a) V 02 = 0.423 eV. (b) V 02 = 0.268 eV. (c) V 02 = 0.127 eV. In Figure 5, we show the effect of confining quantum dot potential on third-order susceptibility. As can be seen with increasing barrier potential,
Alectinib datasheet the third-order susceptibility is decreased and blueshifted. Full-width at half maximum (FWHM) of third-order susceptibility in Figure 5 is approximately ten times broader than the FWHM in Figure 3. Figure 5 Third-order susceptibility versus pump photon wavelength. With different barrier potentials and defect sizes for 1.5-ps relaxation time (black xb = 0.1, red xb = 0.2, and blue xb = 0.3). The effect of relaxation constant (ħΓ) is demonstrated for two well sizes in Figure 6. It can be seen that the peak of the third-order susceptibility is decreased by the increase of the relaxation rate. It is clear from Equation 11 that the third-order susceptibility has an inverse relationship with relaxation constant. Also, the difference between the peak of susceptibilities in a = 15 Å and a = 30 Å is decreased with the increase of relaxation rate.