Dependence of Fermi level positions at gate and substrate on the reliability of ultrathin MOS gate oxides

In this work, we demonstrate that the reliability of ultrathin (<10 nm) gate oxide in MOS devices depends on the Fermi level position at the gate, and not on its position at the substrate for constant current gate injection (υ_g^-). The oxide breakdown strength (Q_bd) is less for p⁺ poly-Si gate than for n⁺ poly-Si gate, but, it is independent of the substrate doping type. The degradation of an oxide is closely related to the electric field across it, which is influenced by the cathode Fermi level for constant current injection. P⁺ poly-Si gate has higher barrier height for tunneled electrons, therefore, the cathode electric field is higher to give the same injection current density. A higher electric field gives more high-energy electrons at the anode, and therefore the damage is more at the substrate interface. We have also shown that oxide degradation is independent of the testing methodology, i.e., constant current or constant voltage stress. It depends mainly on the electric field in the oxide