Large‐Area Flexible Carbon Nanofilms with Synergistically Enhanced Transmittance and Conductivity Prepared by Reorganizing Single‐Walled Carbon Nanotube Networks

Large‐area flexible transparent conductive films (TCFs) are highly desired for future electronic devices. Nanocarbon TCFs are one of the most promising candidates, but some of their properties are mutually restricted. Here, a novel carbon nanotube network reorganization (CNNR) strategy, that is, the...

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Published in:Advanced materials (Weinheim) 2024-06, Vol.36 (26), p.e2313971-n/a
Main Authors: Yue, Ying, Zhang, Di, Wang, Pengyu, Xia, Xiaogang, Wu, Xin, Zhang, Yuejuan, Mei, Jie, Li, Shaoqing, Li, Mingming, Wang, Yanchun, Zhang, Xiao, Wei, Xiaojun, Liu, Huaping, Zhou, Weiya
Format: Article
Language:English
Subjects:
Carbon
Controllability
Dimming
flexibility
Graphene
graphene and single‐walled carbon nanotube hybrid films
large‐areas
Modulus of elasticity
reorganization of carbon nanotube networks
Single wall carbon nanotubes
single‐walled carbon nanotubes
Smart materials
Substrates
Transmittance
transparent conductive films
Windows (apertures)
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Summary:Large‐area flexible transparent conductive films (TCFs) are highly desired for future electronic devices. Nanocarbon TCFs are one of the most promising candidates, but some of their properties are mutually restricted. Here, a novel carbon nanotube network reorganization (CNNR) strategy, that is, the facet‐driven CNNR (FD‐CNNR) technique, is presented to overcome this intractable contradiction. The FD‐CNNR technique introduces an interaction between single‐walled carbon nanotube (SWNT) and Cu─‐O. Based on the unique FD‐CNNR mechanism, large‐area flexible reorganized carbon nanofilms (RNC‐TCFs) are designed and fabricated with A3‐size and even meter‐length, including reorganized SWNT (RSWNT) films and graphene and RSWNT (G‐RSWNT) hybrid films. Synergistic improvement in strength, transmittance, and conductivity of flexible RNC‐TCFs is achieved. The G‐RSWNT TCF shows sheet resistance as low as 69 Ω sq−1 at 86% transmittance, FOM value of 35, and Young's modulus of ≈45 MPa. The high strength enables RNC‐TCFs to be freestanding on water and easily transferred to any target substrate without contamination. A4‐size flexible smart window is fabricated, which manifests controllable dimming and fog removal. The FD‐CNNR technique can be extended to large‐area or even large‐scale fabrication of TCFs and can provide new insights into the design of TCFs and other functional films. A novel facet‐driven carbon nanotube network reorganization method is developed to prepare large‐area flexible freestanding transparent and conductive carbon nanofilms with synergistic enhancement of multiple properties, such as mechanical strength, transmittance and conductivity, and the area up to A3 size and even meter‐length. Based on the film, a new smart window is fabricated.
ISSN:0935-9648
1521-4095
1521-4095
DOI:10.1002/adma.202313971