Performance projections for ballistic carbon nanotube FinFET at circuit level 被引量：6

Performance projections for ballistic carbon nanotube FinFET at circuit level

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摘要 A novel three-dimensional device structure for a carbon nanotube （CNT） fin field-effect transistor （FinFET） is proposed and evaluated. We evaluated the potential of the CNT FinFET compared with a Si FinFET at a 22-nm node at the circuit level using three performance metrics including propagation delay, total power dissipation, and energy-delay product （EDP）. Compared with a Si FinFET, the CNT FinFET presents obvious advantages in speed and EDP arising from its almost much larger current density but also results in a higher total power dissipation, especially at a low threshold voltage （V~ = 1/3Vaa）. A suitable improvement in Vth can effectively contribute to a significant suppression of leakage current and power dissipation, and then an obvious optimization is obtained in the EDP with an acceptable sacrifice in speed. In particular, CNT FinFETs with optimized threshold voltages can provide an EDP advantage of approximately 50 times over Si FinFETs under a low supply voltage （Vdd -- 0.4 V）, suggesting great potential for CNT FinFET-based integrated circuits. A novel three-dimensional device structure for a carbon nanotube （CNT） fin field-effect transistor （FinFET） is proposed and evaluated. We evaluated the potential of the CNT FinFET compared with a Si FinFET at a 22-nm node at the circuit level using three performance metrics including propagation delay, total power dissipation, and energy-delay product （EDP）. Compared with a Si FinFET, the CNT FinFET presents obvious advantages in speed and EDP arising from its almost much larger current density but also results in a higher total power dissipation, especially at a low threshold voltage （V~ = 1/3Vaa）. A suitable improvement in Vth can effectively contribute to a significant suppression of leakage current and power dissipation, and then an obvious optimization is obtained in the EDP with an acceptable sacrifice in speed. In particular, CNT FinFETs with optimized threshold voltages can provide an EDP advantage of approximately 50 times over Si FinFETs under a low supply voltage （Vdd -- 0.4 V）, suggesting great potential for CNT FinFET-based integrated circuits.

作者 Panpan Zhang Chenguang Qiu Zhiyong Zhang Li Ding Bingyan Chen Lianmao Peng

机构地区 Key Laboratory for the Physics and Chemistry of Nanodevices and Department of Electronics

出处《Nano Research》 SCIE EI CAS CSCD 2016年第6期1785-1794,共10页 纳米研究（英文版）

关键词 carbon nanotube fin field-effect transistor（FinFET） integrated circuits multi-threshold voltage carbon nanotube,fin field-effect transistor（FinFET）,integrated circuits,multi-threshold voltage

分类号 TN386 [电子电信—物理电子学] TB383 [一般工业技术—材料科学与工程]

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共引文献1

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同被引文献8

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引证文献6

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