一种改进器件性能的新型扩展后栅负电容TFET

2022 IEEE International Conference of Electron Devices Society Kolkata Chapter (EDKCON) Pub Date : 2022-11-26 DOI:10.1109/EDKCON56221.2022.10032855

Anil Kumar Pathakamuri, C. Pandey

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引用次数: 0

摘要

我们提出了一种具有改进直流性能的新型扩展后栅重叠漏极负电容DGTFET (EBGODDG-NCTFET)。尽管由于引入了铁电层(FE)， EBGODDG-NCTFET在导通电流(ION)和亚阈值摆幅(SS)方面有了很大的改善，但我们还是进行了详细的对比分析，研究了扩展后极重叠漏极对DG-NCTFET双极导通、关断电流和导通电压的影响。所提出的ebgdg - nctfet中，只有后门与漏极重叠，在很大程度上抑制了双极性。这种结构的DG-NCTFET可以通过只使用后门-漏极重叠来解决双极性和寄生电容之间的权衡。由于强大的垂直电场导致漏极区内部损耗更大，EBGODDG-NCTFET漏极/沟道隧穿势垒宽度达到较大值，从而阻止了电荷载流子在双极性状态下隧穿。

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A Novel Extended Back-Gate Negative Capacitance TFET for Improved Device Performance

We propose a novel Extended Back-Gate Overlap-Drain Negative Capacitance DGTFET (EBGODDG-NCTFET) with improved DC performances. Even though EBGODDG-NCTFET shows a great improvement in ON-state current (ION) and subthreshold swing (SS) owing to the introduction of the Ferroelectric (FE) layer, a detailed comparative analysis has been carried out to study the effect of the Extended Back-Gate Overlap-Drain on ambipolar conduction, OFF-state current and turn-on voltage of DG-NCTFET. The proposed EBGODDG-NCTFET in which only the back gate overlaps the drain has been found suppressing the ambipolarity up to a great extent. This structure of DG-NCTFET may resolve the trade-off between ambipolarity and parasitic capacitance by using back gate–drain overlap only. Due to a strong vertical electrical field causing greater depletion inside drain region, width of drain/channel tunneling barrier attains a larger value in EBGODDG-NCTFET, thus preventing charge carriers from tunneling during ambipolar state.

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2022 IEEE International Conference of Electron Devices Society Kolkata Chapter (EDKCON)

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