论文信息 - Outperforming the Conventional Scaling Rules in the Quantum-Capacitance Limit

Outperforming the Conventional Scaling Rules in the Quantum-Capacitance Limit

We present a study on the scaling behavior of field- effect transistors in the quantum-capacitance limit (QCL). It will be shown that a significant performance improvement in terms of the power delay product can be obtained in devices scaled toward the QCL. As a result, nanowires or nanotubes exhibiting a 1-D transport are a premier choice as active channel materials for transistor devices since the QCL can be attained in such systems.

W. Riess | J. Appenzeller | J. Knoch

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