Analysis of biosensing performance of Trench Double Gate Junctionless Field Effect Transistor

Q4 Engineering

Journal of Integrated Circuits and Systems Pub Date : 2024-03-15 DOI:10.29292/jics.v19i1.748

Palasri Dhar, Soumik Poddar, Sunipa Roy

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引用次数: 0

Abstract

Diversified biomolecules sensing is turning out to be the most promising area of research due to ever decreasing healthy lifestyle. Field effect transistorized biosensing approach puts its signature as label free, portable and also very careful pathway. In this present work a trench structured dielectric modulated double gate junction-less field effect transistor (TG-DMJLFET) is urbanized using SILVACO ATLAS simulator for label free detection of biomolecules. The developed structure has two vertically positioned gates in distinct trenches. For immobilizing biomolecules, two cavities are formed in the gate oxide region for dielectric modulation. The dielectric constant (k) has been varied over a wide range of 1.54 (Uricase) to 12(Gelatin) signifying the sensing of diverse charged biomolecules. The sensitivity is evaluated in terms of threshold voltage shift and transconductance . The in-depth electrostatic analysis is illustrated in terms of central potential ,energy band diagram ,drive current and also by the depiction of the electric field .In case of charged biomolecules, the shift in threshold voltage is obtained as 350 mV for change in the di-electric constant (k) ranging from 1.54 to 12. The transconductance alteration is observed as 1.94×10-5 when the k is changed from 3.46 to 12 .The device has showed excellent performance in biomolecules sensing.

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沟槽式双栅极无结场效应晶体管的生物传感性能分析

由于健康生活方式日益减少，多样化的生物分子传感正成为最有前途的研究领域。场效应晶体管生物传感方法具有无标签、便携和非常谨慎的特点。在本研究中，利用 SILVACO ATLAS 仿真器将沟槽结构介质调制双栅极无结场效应晶体管（TG-DMJLFET）城市化，用于无标签生物分子检测。所开发的结构在不同的沟槽中有两个垂直定位的栅极。为了固定生物分子，在栅极氧化物区域形成了两个空腔，用于介电调制。介电常数（k）的变化范围很广，从 1.54（尿酸酶）到 12（明胶），表明可以传感多种带电生物分子。灵敏度通过阈值电压偏移和跨导来评估。通过中心电势、能带图、驱动电流和电场描绘，对静电进行了深入分析。对于带电生物分子，当二介电常数（k）在 1.54 至 12 之间变化时，阈值电压的变化为 350 mV。当 k 值从 3.46 变为 12 时，电导率的变化为 1.94×10-5。该器件在生物分子传感方面表现出卓越的性能。

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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来源期刊

Journal of Integrated Circuits and Systems Engineering-Electrical and Electronic Engineering

CiteScore

0.90

自引率

0.00%

发文量

期刊介绍： This journal will present state-of-art papers on Integrated Circuits and Systems. It is an effort of both Brazilian Microelectronics Society - SBMicro and Brazilian Computer Society - SBC to create a new scientific journal covering Process and Materials, Device and Characterization, Design, Test and CAD of Integrated Circuits and Systems. The Journal of Integrated Circuits and Systems is published through Special Issues on subjects to be defined by the Editorial Board. Special issues will publish selected papers from both Brazilian Societies annual conferences, SBCCI - Symposium on Integrated Circuits and Systems and SBMicro - Symposium on Microelectronics Technology and Devices.