Preparation and Properties of Graphene-based Conductive Paper

doi:10.11901/1005.3093.2015.479

Chinese Journal of Materials Research

2016, Vol. 30

Issue (11): 855-860 DOI: 10.11901/1005.3093.2015.479

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Preparation and Properties of Graphene-based Conductive Paper

Songnan NAN^1,²,Hongwei ZHANG¹,Qingwen WANG^1,^**(

)

1. State Key Lab of Pulp and Paper Engineering, South China University of Technology, Guangzhou 510640, China
2. Patent Examination Cooperation Center of the Patent Office, SIPO, Zhengzhou 450002, China

Cite this article:

Songnan NAN, Hongwei ZHANG, Qingwen WANG. Preparation and Properties of Graphene-based Conductive Paper. Chinese Journal of Materials Research, 2016, 30(11): 855-860.

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Abstract

Tea polyphenols and aluminum flakes was utilized as the reductants to reduce graphene oxide and then synthesize graphene, the as-prepared graphene was then to prepare the graphene-based conductive paper recombination with cellulose. The influence of composite ratio between cellulose and graphene, the conductive paper ration, the folding times and angles to the conductive paper’s electrical property were discussed. The results show that graphene oxide can be reduced effectively by tea polyphenols and aluminum flakes, the sp²structure can be restored effectively. The optimal conditions is composite ratio between cellulose and graphene 1:1, the conductive paper ration 72 g/m², the sheet resistanceand elasticity modulus of the as-prepared conductive paper is 66.33 Ω/sqand 1234.00 MPa. The conductive paper reserved good conductivity after 500 times folding and different folding angles, the ratio between after-folded resistanceand initial resistance is near 1.0. Besides, the specific capacitance of the conductive paper is 5.47 mF/cm², which suggests a good capacitive performance.

Key words: inorganic non-metallic materials cellulose grapheme conductive paper sheet resistance

Received: 27 August 2015

Fund: *Supported by State Key Laboratory of Pulp and Paper Engineering Nos. 2014C24, ZD201401 & 2016C13.

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	Songnan NAN
	Hongwei ZHANG
	Qingwen WANG

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https://www.cjmr.org/EN/10.11901/1005.3093.2015.479 OR https://www.cjmr.org/EN/Y2016/V30/I11/855

Fig.1 Preparation process of graphene-based conductive paper

Fig.2 FTIR spectra of GO and RGO

Fig.3 AFM images of RGO nanosheets

Fig.4 Influence of different composite ratio between cellulose and graphene to conductive paper's sheet resistance

Fig.5 Influence of different composite ratio between cellulose and graphene to conductive paper's elasticity modulus

Fig.6 Influence of paper weight to conductive paper's sheet resistance

Fig.7 Influence of paperweight to conductive paper's elasticity modulus

Fig.8 Influence of folding cycles and angels to the conduction stability of conductive paper

Fig.9 Electrical pathways presentation of conductive paper (a) Bending angle is 0° (b) bending angle is 90°

Fig.10 CV curves of graphene-based conductive paper

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