Electrolyte‐gated organic field‐effect transistors with high operational stability and lifetime in practical electrolytes

SmartMat Pub Date : 2024-06-14 DOI:10.1002/smm2.1291
D. Simatos, M. Nikolka, J. Charmet, L. Spalek, Z. Toprakcioglu, Ian E. Jacobs, I. Dimov, G. Schweicher, Mi Jung Lee, C. Fernández-Posada, Duncan J. Howe, T. Hakala, L. W. Roode, Vincenzo Pecunia, Thomas P. Sharp, Weimin Zhang, Maryam Alsufyani, Iain McCulloch, T. Knowles, Henning Sirringhaus
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Abstract

A key component of organic bioelectronics is electrolyte‐gated organic field‐effect transistors (EG‐OFETs), which have recently been used as sensors to demonstrate label‐free, single‐molecule detection. However, these devices exhibit limited stability when operated in direct contact with aqueous electrolytes. Ultrahigh stability is demonstrated to be achievable through the utilization of a systematic multifactorial approach in this study. EG‐OFETs with operational stability and lifetime several orders of magnitude higher than the state of the art have been fabricated by carefully controlling a set of intricate stability‐limiting factors, including contamination and corrosion. The indacenodithiophene‐co‐benzothiadiazole (IDTBT) EG‐OFETs exhibit operational stability that exceeds 900 min in a variety of widely used electrolytes, with an overall lifetime exceeding 2 months in ultrapure water and 1 month in various electrolytes. The devices were not affected by electrical stress‐induced trap states and can remain stable even in voltage ranges where electrochemical doping occurs. To validate the applicability of our stabilized device for biosensing applications, the reliable detection of the protein lysozyme in ultrapure water and in a physiological sodium phosphate buffer solution for 1500 min was demonstrated. The results show that polymer‐based EG‐OFETs are a viable architecture not only for short‐term but also for long‐term biosensing applications.
在实用电解质中具有高工作稳定性和使用寿命的电解质门控有机场效应晶体管
有机生物电子学的一个关键元件是电解质门控有机场效应晶体管(EG-OFET),这种器件最近被用作传感器,演示了无标记的单分子检测。然而,这些器件在与水性电解质直接接触时表现出有限的稳定性。本研究采用系统的多因素方法,证明可以实现超高稳定性。通过对一系列错综复杂的稳定性限制因素(包括污染和腐蚀)的精心控制,我们制造出了工作稳定性和寿命比目前技术水平高出几个数量级的 EG-OFET 器件。茚并噻吩-共苯并噻二唑(IDTBT)EG-OFET 在各种广泛使用的电解质中的工作稳定性超过 900 分钟,在超纯水中的总体寿命超过 2 个月,在各种电解质中的总体寿命超过 1 个月。这些器件不受电应力诱导阱态的影响,即使在发生电化学掺杂的电压范围内也能保持稳定。为了验证我们的稳定器件在生物传感应用中的适用性,我们在超纯水和生理磷酸钠缓冲溶液中对溶菌酶蛋白进行了 1500 分钟的可靠检测。结果表明,基于聚合物的 EG-OFET 是一种可行的结构,不仅适用于短期生物传感应用,也适用于长期生物传感应用。
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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