Nano-biosensors with subthreshold swing tunnel field effect transistor: A cutting-edge review

IF 5.4 Q1 CHEMISTRY, ANALYTICAL Sensing and Bio-Sensing Research Pub Date : 2024-06-01 DOI:10.1016/j.sbsr.2024.100665

M. Poorna Sundari , G. Lakshmi Priya

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Abstract

A thorough investigation into the development and performance assessment of biosensors that utilize Tunnel Field Effect Transistors (TFETs), showcasing a departure from conventional bio-sensing approaches is carried out. The unique properties of TFETs leverage quantum tunneling effects to enable precise and efficient detection of biomolecules. This review examines the impact of various device schematic modifications on the sensitivity of TFET biosensors. The analysis focuses on methodologies aimed at improving sensitivity levels, exploring models from scholarly literature, and assessing shifts in simulated parameters. Such as ON current (I_ON), Subthreshold Swing (SS), OFF current (I_OFF), ON-OFF current ratio (I_ON/I_OFF), threshold voltage (V_th), sensitivity, and selectivity. Among different architectures reported in the work, Heterojunction Tunneling Field Effect Transistor (HJ-TFET)-based biosensors offer significant advancements in biosensing technology due to their ability to control tunneling rates through versatile bandgap materials. Vertical TFET (VTFET) biosensors also demonstrate promising potential for label-free and specific biomolecule detection, leveraging vertical architectures for enhanced electrostatic control and scalability. Incorporating negative capacitance effects through ferroelectric materials further improves the VTFET performance, with ultra-low subthreshold swing and high sensitivity. Through the exploration of the latest advancements and applications, we illustrate how these nano-enabled gateways to health are opening up new possibilities for rapid, on-site medical diagnostics, ultimately bringing cutting-edge healthcare solutions. By drawing comparisons with established biosensing methods, TFET-based biosensors show immense promise in transforming medical diagnostics and point-of-care applications, offering high sensitivity which is crucial for precise monitoring in various fields such as medical diagnostics, environmental monitoring, and food safety.

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采用亚阈值摆动隧道场效应晶体管的纳米生物传感器：前沿综述

本文对利用隧道场效应晶体管（TFET）的生物传感器的开发和性能评估进行了深入研究，展示了与传统生物传感方法的不同之处。隧道场效应晶体管的独特性能可利用量子隧道效应实现对生物分子的精确、高效检测。本综述探讨了各种器件原理修改对 TFET 生物传感器灵敏度的影响。分析的重点是旨在提高灵敏度水平的方法、探索学术文献中的模型以及评估模拟参数的变化。这些参数包括导通电流 (ION)、阈下波动 (SS)、关断电流 (IOFF)、导通关断电流比 (ION/IOFF)、阈值电压 (Vth)、灵敏度和选择性。在这项工作所报告的不同架构中，基于异质结隧道场效应晶体管（HJ-TFET）的生物传感器通过多功能带隙材料控制隧道速率的能力，大大推动了生物传感技术的发展。垂直场效应晶体管（VTFET）生物传感器还利用垂直结构增强了静电控制和可扩展性，在无标记和特异性生物分子检测方面展现出巨大潜力。铁电材料的负电容效应进一步提高了 VTFET 的性能，使其具有超低阈下摆动和高灵敏度。通过对最新进展和应用的探讨，我们说明了这些纳米健康门户如何为快速现场医疗诊断开辟新的可能性，并最终带来尖端的医疗解决方案。通过与已有的生物传感方法进行比较，基于 TFET 的生物传感器在改变医疗诊断和护理点应用方面展现出巨大的前景，其高灵敏度对于医疗诊断、环境监测和食品安全等各个领域的精确监测至关重要。

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来源期刊

Sensing and Bio-Sensing Research Engineering-Electrical and Electronic Engineering

CiteScore

10.70

自引率

3.80%

发文量

审稿时长

87 days

期刊介绍： Sensing and Bio-Sensing Research is an open access journal dedicated to the research, design, development, and application of bio-sensing and sensing technologies. The editors will accept research papers, reviews, field trials, and validation studies that are of significant relevance. These submissions should describe new concepts, enhance understanding of the field, or offer insights into the practical application, manufacturing, and commercialization of bio-sensing and sensing technologies. The journal covers a wide range of topics, including sensing principles and mechanisms, new materials development for transducers and recognition components, fabrication technology, and various types of sensors such as optical, electrochemical, mass-sensitive, gas, biosensors, and more. It also includes environmental, process control, and biomedical applications, signal processing, chemometrics, optoelectronic, mechanical, thermal, and magnetic sensors, as well as interface electronics. Additionally, it covers sensor systems and applications, µTAS (Micro Total Analysis Systems), development of solid-state devices for transducing physical signals, and analytical devices incorporating biological materials.