Improved Design and Comparison of a Low Power CNTFET based on D Flip-Flop

2023 International Conference on Electrical, Computer and Communication Engineering (ECCE) Pub Date : 2023-02-23 DOI:10.1109/ECCE57851.2023.10101615

Jahid Hasan Ridoy, Atik Yasir Rahman, Fahad Raihan Saquib

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Abstract

Carbon nanotube field effect transistors (CNTFETs) are auspicious nanoscale devices for realizing high performance with very thick and low power circuits. In this paper, different parameters of CNTFET from previous works have been studied and analyzed. Then, leakage current and leakage power of the proposed D flip-flop were compared with different reference circuits. The main goal is to improve, develop and design a CNTFET based D flip-flop. CNTFET's leakage current and leakage power consumption reduced drastically by decreasing diameter of CNT and number of CNT used in the CNTFET, which affected overall CNTFET's power consumption obviously. The proposed D flip-flop exhibited exquisite performance in case of leakage power consumption, having an average of 10.306 nW only, which is extremely low compared to the contemporary circuits. The chosen thickness of oxide and CNT's length for all the CNTFETs are 5 nm and 16 nm respectively. These CNTFETs are based on the results gathered from so that not only they can act as a D flip-flop correctly but also total power consumption of the device would be reduced as much as possible.

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基于D触发器的低功耗CNTFET的改进设计与比较

碳纳米管场效应晶体管(cntfet)是用极厚低功耗电路实现高性能的理想纳米器件。本文对前人研究的CNTFET的不同参数进行了研究和分析。然后比较了不同参考电路中D触发器的漏电流和漏功率。主要目标是改进、开发和设计一个基于CNTFET的D触发器。通过减小碳纳米管直径和碳纳米管个数，碳纳米管的漏电流和漏功耗显著降低，对碳纳米管的整体功耗有明显影响。所提出的D触发器在漏功耗情况下表现出色，平均功耗仅为10.306 nW，与当代电路相比极低。所选择的氧化层厚度和碳纳米管长度分别为5nm和16nm。这些cntfet是基于收集的结果，这样不仅可以正确地充当D触发器，而且可以尽可能地降低器件的总功耗。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2023 International Conference on Electrical, Computer and Communication Engineering (ECCE)

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