We investigate the binding energies of excitons in a strained (111)-oriented zinc-blende GaN/Al0.3 Ga0.7 N quantum well screened by the electron-hole (e-h) gas under hydrostatic pressure by combining a variational...We investigate the binding energies of excitons in a strained (111)-oriented zinc-blende GaN/Al0.3 Ga0.7 N quantum well screened by the electron-hole (e-h) gas under hydrostatic pressure by combining a variational method and a selfconsistent procedure. A built-in electric field produced by the strain-induced piezoelectric polarization is considered in our calculations. The result indicates that the binding energies of excitons increase nearly linearly with pressure,even though the modification of strain with hydrostatic pressure is considered, and the influence of pressure is more apparent under higher e-h densities. It is also found that as the density of an e-h gas increases,the binding energies first increase slowly to a maximum and then decrease rapidly when the e-h density is larger than about 1 ×10^11 cm^-2. The excitonic binding energies increase obviously as the barrier thickness decreases due to the decrease of the built-in electric field.展开更多
文摘We investigate the binding energies of excitons in a strained (111)-oriented zinc-blende GaN/Al0.3 Ga0.7 N quantum well screened by the electron-hole (e-h) gas under hydrostatic pressure by combining a variational method and a selfconsistent procedure. A built-in electric field produced by the strain-induced piezoelectric polarization is considered in our calculations. The result indicates that the binding energies of excitons increase nearly linearly with pressure,even though the modification of strain with hydrostatic pressure is considered, and the influence of pressure is more apparent under higher e-h densities. It is also found that as the density of an e-h gas increases,the binding energies first increase slowly to a maximum and then decrease rapidly when the e-h density is larger than about 1 ×10^11 cm^-2. The excitonic binding energies increase obviously as the barrier thickness decreases due to the decrease of the built-in electric field.
