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13.04.2020 | Communication

Transparent and conductive cellulose film by controllably growing aluminum doped zinc oxide on regenerated cellulose film

verfasst von: Xi Liu, Kaixin Huang, Xinxing Lin, Huixin Li, Tao Tao, Qinhan Wu, Qinghong Zheng, Liulian Huang, Yonghao Ni, Lihui Chen, Xinhua Ouyang, Jianguo Li

Erschienen in: Cellulose | Ausgabe 9/2020

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Abstract

Functional applications of cellulose have attracted large amount of attentions owing to its natural, environmentally friendly, light-weight characteristics. In this study, a cellulose-based conductive film (CCF) was prepared by sputtering aluminum doped zinc oxide (AZO, a cheap and non-toxic semiconductor) on a regenerated cellulose film from bamboo fibers. Through dissolution and regenerated process of cellulose fibers, the as-prepared cellulose film featured high transmittance of 97% and low roughness of 0.943 nm as well as 117 MPa strength, which can be supportive for manufacturing cellulose-based conductive devices. Based on the cellulose film which was as the transparent substate, we systematically investigated the effects of working parameters on the performance of AZO-based cellulose conductive film, followed by a phenomenon that the crystal structure and morphology of AZO particles play decisive role on the transmittance and conductivity of CCF. With the optimized working parameters, the CCF presented low conductive resistance of 365 Ω/□, high transmittance of 86% and high-quality crystalline structure. Besides, the thermal stability and mechanical strength of CCF were also investigated. The prepared CCF is beneficial for manufacturing the transparently electronic devices with environmental-friendly merit.

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Titel: Transparent and conductive cellulose film by controllably growing aluminum doped zinc oxide on regenerated cellulose film
verfasst von: Xi Liu
Kaixin Huang
Xinxing Lin
Huixin Li
Tao Tao
Qinhan Wu
Qinghong Zheng
Liulian Huang
Yonghao Ni
Lihui Chen
Xinhua Ouyang
Jianguo Li
Publikationsdatum: 13.04.2020
Verlag: Springer Netherlands
Erschienen in: Cellulose / Ausgabe 9/2020
Print ISSN: 0969-0239
Elektronische ISSN: 1572-882X
DOI: https://doi.org/10.1007/s10570-020-03147-0

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