栅极介电堆直接隧穿电流的建模

2000 International Conference on Simulation Semiconductor Processes and Devices (Cat. No.00TH8502) Pub Date : 2000-10-01 DOI:10.1109/SISPAD.2000.871242

S. Mudanai, Y.-Y. Fan, Q. Ouyang, A. Tasch, F. Register, D. Kwong, S. Banerjee

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引用次数: 63

摘要

通过数值求解薛定谔方程，并考虑波函数穿透栅极介电层，首次计算了从倒p衬底穿过不同栅极介电层的直接隧穿电流。数值解采用一阶摄动方法计算准束缚态的寿命。这种方法已被证实是有效的，即使是极薄的电介质(0.5 nm)。WKB解与该技术预测的隧道电流吻合得很好。在相同的有效氧化物厚度(EOT)下，直接隧穿电流随介电常数的增大而减小。然而，为了充分利用高k介电体作为栅极绝缘体，必须消除界面氧化物。我们还首次给出了假设波函数穿透到氧化物中得到的C-V曲线。

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Modeling of direct tunneling current through gate dielectric stacks

The direct tunneling current has been calculated for the first time from an inverted p-substrate through different gate dielectrics by numerically solving Schrodinger's equation and allowing for wave function penetration into the gate dielectric stack. The numerical solution adopts a first-order perturbation approach to calculate the lifetime of the quasi-bound states. This approach has been verified to be valid even for extremely thin dielectrics (0.5 nm). The WKB solution agrees well with the tunneling currents predicted by this technique. For the same effective oxide thickness (EOT), the direct tunneling current decreases with increasing dielectric constant, as expected. However, in order to take full advantage of using high-k dielectrics as gate insulators, the interfacial oxide must be eliminated. We also present for the first time the C-V curves obtained assuming that the wave function penetrates into the oxide.

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2000 International Conference on Simulation Semiconductor Processes and Devices (Cat. No.00TH8502)

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