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The impact of quantum confinement on the electrical characteristics of ultrathin-channel GeOI nMOSFETs is investigated on the basis of the density-gradient model in TCAD software. The effects of the channel thickness(Tch/ and back-gate bias(Vbg/ on the electrical characteristics of GeOI MOSFETs are examined, and the simulated results are compared with those using the conventional semi-classical model. It is shown that when Tch> 8 nm, the electron conduction path of the GeOI MOSFET is closer to the front-gate interface under the QC model than under the CL model, and vice versa when Tch< 8 nm. Thus the electrically controlled ability of the front gate of the devices is influenced by the quantum effect. In addition, the quantum-mechanical mechanism will enhance the drain-induced barrier lowering effect, increase the threshold voltage and decrease the on-state current;for a short channel length(6 30 nm), when Tch > 8 nm(or < 8 nm), the quantum-mechanical mechanism mainly impacts the subthreshold slope(or the threshold voltage). Due to the quantum-size effect, the off-state current can be suppressed as the channel thickness decreases.
The impact of quantum confinement on the electrical characteristics of ultrathin-channel GeOI nMOSFETs is investigated on the basis of the density-gradient model in TCAD software. The effects of the channel thickness (Tch / and back-gate bias (Vbg / on the electrical characteristics of GeOI MOSFETs are examined, and the use of the conventional semi-classical model. It is shown that when Tch> 8 nm, the electron conduction path of the GeOI MOSFET is closer to the front-gate interface under the QC model than under the CL model, and vice versa when Tch <8 nm. Thus the electrically controlled ability of the front gate of the devices is influenced by the quantum effect. In addition, the quantum-mechanical mechanism will enhance the drain- the quantum-mechanical mechanism mainly impacts the subthr (or <8 nm) when Tch> 8 nm (or <8 nm) Due to the quantum-size effect, the off-state current can be suppressed as the channel thickness decreases.