Analysis of quasi-ballistic hole transport capability of Ge and Si nanowire pMOSFETs by a quantum-corrected Boltzmann transport equation

机译：通过量子校正的玻耳兹曼输运方程分析Ge和Si纳米线pMOSFET的准弹道空穴传输能力

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The quasi-ballistic hole transport capabilities of Ge and Si nanowire pMOSFETs were analyzed based on a quantum- corrected Boltzmann transport equation. A new formalism of quantum-correction potential was proposed, and using this model, the current drive capabilities of Ge and Si nanowire pMOSFETs were compared. Though the ON-current was larger in the Ge nanowire pMOSFET, the transmission coefficients are similar between Ge and Si, because the higher hole mobility of Ge is canceled by its slower energy relaxation. Thus, the larger current of the Ge nanowire pMOSFET was attributed to its larger injection current. The impact of device geometry on the performance was also investigated, and the [110]-oriented Ge nanowire pMOSFET with a 15 nm gate length exhibited the highest performance among the devices considered in this study.

机译：基于量子校正的玻耳兹曼输运方程，分析了Ge和Si纳米线pMOSFET的准弹道空穴传输能力。提出了一种新的量子校正势形式，并使用该模型对Ge和Si纳米线pMOSFET的电流驱动能力进行了比较。尽管Ge纳米线pMOSFET的导通电流较大，但是Ge和Si之间的传输系数相似，这是因为Ge的较高空穴迁移率被较慢的能量弛豫抵消了。因此，Ge纳米线pMOSFET的较大电流归因于其较大的注入电流。还研究了器件几何形状对性能的影响，在研究中考虑的器件中，栅长为15 nm的[110]取向的Ge纳米线pMOSFET表现出最高的性能。

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《International Conference on Simulation of Semiconductor Processes and Devices》|2017年|277-280|共4页
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Hajime Tanaka; Jun Suda; Tsunenobu Kimoto;
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MOSFET; Silicon; Electric potential; Logic gates; Boltzmann equation; Mathematical model; Nanoscale devices;

机译：MOSFET;硅;电势;逻辑门;玻尔兹曼方程;数学模型;纳米尺度器件;

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2. Impacts of energy relaxation process on quasi-ballistic hole transport capability in germanium and silicon nanowires [J] . H. Tanaka, J. Suda, T. Kimoto Journal of Applied Physics . 2018,第2期

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3. Analysis of ballistic and quasi-ballistic hole transport properties in germanium nanowires based on an extended "Top of the Barrier" model [J] . Tanaka Hajime, Suda Jun, Kimoto Tsunenobu Solid-State Electronics . 2016,第SEPa期

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4. Analysis of quasi-ballistic hole transport capability of Ge and Si nanowire pMOSFETs by a quantum-corrected Boltzmann transport equation [C] . Hajime Tanaka, Jun Suda, Tsunenobu Kimoto International Conference on Simulation of Semiconductor Processes and Devices . 2017

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Analysis of quasi-ballistic hole transport capability of Ge and Si nanowire pMOSFETs by a quantum-corrected Boltzmann transport equation

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