Abstract

Carbon nanotube (CNT)-doped transparent conductive films (TCFs) is an encouraging option toward generally utilized indium tin oxide-depended TCFs for prospective stretchable optoelectronic materials. Industrial specifications of TCFs involve not just with high electrical performance and transparency but also amidst environmental resistance and mechanical characteristic; those are usually excused within the research background. Though the optoelectronic properties of these sheets require to be developed to match the necessities of various strategies. While, the electrical stability of single-walled CNT TCFs is essentially circumscribed through the inherent resistivity of single SWCNTs and their coupling confrontation in systems. The main encouraging implementations, CNT-doped TCFs, is a substitute system during approaching electronics to succeed established TCFs, that utilize indium tin oxide. Here we review, a thorough summary of CNT-based TCFs including an overview, properties, history, synthesis protocol covering patterning of the films, properties and implementation. There is the attention given on the optoelectronic features of films and doping effect including applications for sophisticated purposes. Concluding notes are given to recommend a prospective investigation into this field towards real-world applicability.

Graphic abstract

This graphical abstract shows the overview of different properties (mechanical, electrical, sensitivity and transportation), synthesis protocols and designing (dry and wet protocol, designing by surface cohesive inkjet-printed and the support of polymers), doping effect (general doping, metal halides, conductive polymers and graphene for transparent electrodes) and implementations (sensing panels, organic light-emitting diodes devices, thin-film transistors and bio-organic interface) of carbon nanotubes transparent conductive films.

中文翻译：

---

透明碳纳米管薄膜的最新进展：化学和迫在眉睫的挑战

摘要

掺杂碳纳米管（CNT）的透明导电膜（TCF）是朝着普遍使用的依赖于铟锡氧化物的TCF的令人鼓舞的选择，用于预期的可拉伸光电材料。TCF的工业规格不仅涉及高电气性能和透明度，而且还涉及耐环境性和机械特性。这些通常是在研究背景中被原谅的。尽管需要开发这些片的光电性能以匹配各种策略的必要性。同时，单壁CNT TCF的电稳定性基本上是通过单个SWCNT的固有电阻率及其在系统中的耦合作用来限制的。令人鼓舞的主要实现方式是CNT掺杂的TCF，是在接近电子产品以成功建立利用铟锡氧化物的TCF时的替代系统。在这里，我们回顾了基于CNT的TCF的详尽摘要，包括概述，特性，历史，涵盖膜图案，特性和实现的合成协议。人们对薄膜的光电特性和掺杂效果给予了关注，包括用于复杂目的的应用。最后的结论是建议对这个领域进行前瞻性研究，以求在现实世界中具有适用性。人们对薄膜的光电特性和掺杂效果给予了关注，包括用于复杂目的的应用。最后的结论是建议对这个领域进行前瞻性研究，以求在现实世界中具有适用性。人们对薄膜的光电特性和掺杂效果给予了关注，包括用于复杂目的的应用。最后的结论是建议对这个领域进行前瞻性研究，以求在现实世界中具有适用性。

图形摘要

该图形摘要显示了不同属性（机械，电气，灵敏度和传输），合成规程和设计（干法和湿法规程，通过表面粘合喷墨印刷进行的设计以及聚合物的支持），掺杂效果（常规掺杂，金属）的概述碳纳米管透明导电膜的卤化物，导电聚合物和石墨烯作为透明电极）和实现方式（传感面板，有机发光二极管器件，薄膜晶体管和生物有机界面）。