Inkjet-printed flexible MXetronics: Present status and future prospects

Rajavel Krishnamoorthy, Suprem R. Das
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Abstract

Over the past several years, atomically thin two-dimensional carbides, nitrides, and carbonitrides, otherwise known as MXenes, have been expanded into over fifty material candidates that are experimentally produced, and over one hundred fifty more candidates that have been theoretically predicted. They have demonstrated transformative properties such as metallic-type electrical conductivities, optical properties such as plasmonics and optical nonlinearity, and key surface properties such as hydrophilicity, and unique surface chemistry. In terms of their applications, they are poised to transform technological areas such as energy storage, electromagnetic shielding, electronics, photonics, optoelectronics, sensing, and bioelectronics. One of the most promising aspects of MXene's future application in all the above areas of interest, we believe, is reliably developing their flexible and bendable electronics and optoelectronics by printing methods (henceforth, termed as printed flexible MXetronics). Designing and manipulating MXene conductive inks according to the application requirements will therefore be a transformative goal for future printed flexible MXetronics. MXene's combined property of high electrical conductivity and water-friendly nature to easily disperse its micro/nano-flakes in an aqueous medium without any binder paves the way for designing additive-free highly conductive MXene ink. However, the chemical and/or structural and hence functional stability of water based MXene inks over time is not reliable, opening research avenues for further development of stable and conductive MXene inks. Such priorities will enable applications requiring high-resolution and highly reliable printed MXene electronics using state-of-the art printing methods. Engineering MXene structural and surface functional properties while tuning MXene ink rheology in benign solvents of choice will be a key for ink developments. This review article summarizes the present status and prospects of MXene inks and their use in inkjet-printed (IJP) technology for future flexible and bendable MXetronics.

Abstract Image

喷墨打印柔性 MXetronics:现状与前景
在过去的几年中,原子薄二维碳化物、氮化物和碳氮化物(又称 MXenes)已扩展为五十多种实验生产的候选材料,以及一百五十多种理论预测的候选材料。它们已显示出变革性的特性,如金属型导电性、等离子体和光学非线性等光学特性,以及亲水性和独特的表面化学性等关键表面特性。在应用方面,它们有望在未来改变能源存储、电磁屏蔽、电子学、光子学、光电子学、传感和生物电子学等技术领域。我们认为,MXene 未来在上述所有领域最有前景的应用之一,是通过印刷方法开发柔性可弯曲电子和光电子技术(以下称为印刷柔性 MXetronics)。因此,根据应用要求设计和处理 MXene 导电油墨将是未来印刷电子技术的一个变革性目标。MXene 具有高导电性和亲水性的双重特性,可在水介质中轻松分散其微/纳米薄片而无需任何粘合剂,这为设计无添加剂的高导电性 MXene 油墨铺平了道路。然而,水基 MXene 油墨的化学稳定性和/或结构稳定性以及功能稳定性并不可靠,这为进一步开发稳定的导电 MXene 油墨开辟了研究途径。这些优先事项将有助于利用最先进的印刷方法实现需要高分辨率和高可靠性印刷 MXene 电子元件的应用。设计 MXene 的结构和表面功能特性,同时调整 MXene 油墨在所选溶剂中的流变性将是油墨开发的关键。这篇综述文章总结了 MXene 油墨的现状和前景,以及它们在喷墨打印 (IJP) 技术中的应用,以实现未来柔性和可弯曲的 MXetronics。本文受版权保护,保留所有权利。
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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