TUNNELING ASSISTED THERMIONIC EMISSION IN DOUBLE-BARRIER QUANTUM-WELL STRUCTURES

We report on experimental and theoretical investigations of the dark current behavior in n-type GaAs/AlAs/Al0.3Ga0.7As double-barrier quantum wells (DBQW). The dark current perpendicular to the 50-period DBQW structures shows evidence of tunneling through the 2-nm-wide AlAs tunnel barriers and thermionic emission across the 25-nm-wide AlGaAs layers. The temperature dependence is in good agreement with our numerical simulations, using an effective escape rate of 2.2×1014 s-1. The dark current is further modified by internal electric fields caused by an asymmetric dopant distribution, which partially arises from a dopant segregation during epitaxial growth. We also present a theoretical simulation showing how the dark current versus voltage dependence is influenced by these space-charge fields. © 1995 American Institute of Physics.