Figure 1: Schematic cross-section along y-axis of the cor/shell strucure.
FIGURE 2
Figure 2: NOR versus incident photon energy for different core radius
FIGURE 3
Figure 3: Energies eigen values of the ground and first excited states and the resonant energy ?res as a function of the core radius
FIGURE 4
Figure 4: NOR magnitude (left) and the geometrical factor (right) as a function of the core radius
FIGURE 5
Figure 5: Probability of finding electron inside the core region (PC), the shell region (PS), and in the wetting layer (PWL) as a function of the core radius for: (a) the ground energy level and (b) the first excited energy level
FIGURE 6
Figure 6: NOR coefficient versus the incident photon energy with and without the wetting layer and for two different values of the core height
FIGURE 7
Figure 7: NOR magnitude versus the angle F for different electric field intenisties
FIGURE 8
Figure 8: NOR magnitude (left axis) and the geometrical factor (right axis) versus the electric field intensity for F=0)
FIGURE 9
Figure 9: The resonant energy versus the electric field intensity for F=0 (energies eigen values of the ground and first excited states are depicted by the sketched figure)
FIGURE 10
Figure 10: The NOR as a function of the incident photon energy for different electric field intensities and orionatations (the sketched figure is a zoom of the spectrum (a)
FIGURE 11
Figure 11: Combined effects of pressure, temperature, electromagnetic fields and wetting layer on the NOR spectrum
FIGURE 12
Figure 12: Pressure, temperature and electromagnetic fields effects on the transition lifetime of carriers
FIGURE 13
Figure 13: Temperature and electric field intensity effects on the transition dipole matrix element (left axis) and on the transition energy (right axis)
Figures at a glance