Effect of Graphene Oxide Mass Concentration on Properties of Nickel-based Graphene Composite Electroforming Layer under Supercritical Condition

WANG Yunqiang; LEI Weining; SHEN Yu; QIAN Haifeng; LI Qilin; LI Xiaoping

doi:10.11973/jxgccl201708003

Materials and Mechanical Engineering > 2017 > 41(8): 12-17. > DOI: 10.11973/jxgccl201708003

WANG Yunqiang, LEI Weining, SHEN Yu, QIAN Haifeng, LI Qilin, LI Xiaoping. Effect of Graphene Oxide Mass Concentration on Properties of Nickel-based Graphene Composite Electroforming Layer under Supercritical Condition[J]. Materials and Mechanical Engineering, 2017, 41(8): 12-17. DOI: 10.11973/jxgccl201708003

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Effect of Graphene Oxide Mass Concentration on Properties of Nickel-based Graphene Composite Electroforming Layer under Supercritical Condition

1. School of Mechanical Engineering, Jiangsu University of Technology, Changzhou 213001, China;
2. Jiangsu Province Key Laboratory of High Performance Material Green Forming and Equipment, Jiangsu University of Technology, Changzhou 213001, China

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Received Date: July 28, 2016
Revised Date: June 24, 2017

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Abstract

A nickel-based graphene composite electroforming layer was prepared under supercritical and ordinary conditions, respectively. The effects of two preparation conditions and graphene oxide (GO) mass concentration on the microstructure, surface morphology, hardness and wear resistance of the composite electroforming layer were investigated. The results show that comparing to those under the ordinary condition, the microstructure of the composite electroforming layer under the supercritical condition was compact and the surface roughness was lower; the preferred degree of the Ni crystal face (111) and (220) decreased while that of the crystal face (220) increased; the hardness and wear resistance were improved. Under the supercritical condition, with the increase of the GO mass concentration, the microhardness, wear resistance and the embedding amount of graphene nanosheets all first increased then decreased. When the GO mass concentration was 0.20 g·L^-1, the graphene content in the composite electroforming layer was the highest, and the microhardness reached the largest value of 768 HV, also the relative wear resistance was the best.
- supercritical carbon dioxide fluid,
- graphene,
- composite electroforming layer,
- microstructure,
- hardness,
- wear resistance

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Effect of Graphene Oxide Mass Concentration on Properties of Nickel-based Graphene Composite Electroforming Layer under Supercritical Condition

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