Abstract
In this paper, we present a computationally efficient model to calculate the direct tunneling current from an inverted p-type (1 0 0) Si substrate through interfacial SiO 2 and high- K gate stacks. This model consists of quantum mechanical calculations for the inversion layer charge density and a modified WKB approximation for the transmission probability. The modeled direct tunneling currents agree well with a self-consistent model and experimental data. For the same effective oxide thickness (EOT) of 2 nm, the direct tunneling current of a HfO 2 high- K dielectric (6.4 nm, K f=25) overlaying a 1 nm thermal oxide is reduced by four orders of magnitude compared with a pure SiO 2 film at low gate voltages. The effects of interfacial oxide thickness, dielectric constant and barrier height on the direct tunneling current have also been studied as a function of gate voltages.
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