In-situ grown continuous graphene network enhances the electrical conductivity and tribological properties of copper matrix composites

Liangliang Zeng; Yilong Liang; Peng Chen

doi:10.1007/s11706-024-0704-x

Front. Mater. Sci. ›› 2024, Vol. 18 ›› Issue (4) : 240704 DOI: 10.1007/s11706-024-0704-x

RESEARCH ARTICLE

In-situ grown continuous graphene network enhances the electrical conductivity and tribological properties of copper matrix composites

Liangliang Zeng ¹^,²^,³
, Yilong Liang ¹^,²^,³^,^†
, Peng Chen ¹^,²^,³

Author information +

History +

PDF (5615KB)

Abstract

Copper has good electrical conductivity but poor mechanical and wear-resistant properties. To enhance the mechanical and wear-resistant properties of the copper matrix, a strategy of in-situ generation of graphene was adopted. Through ball-milling processes, a carbon source and submicron spherical copper were uniformly dispersed in a dendritic copper. Then, a uniform and continuous graphene network was generated in-situ in the copper matrix during the vacuum hot-pressing sintering process to improve the performance of composites. The graphene product exhibited lubrication effect and provided channels for electrons to move through the interface, improving the wear resistance and the electrical conductivity of composites. When the graphene content in the composite material was 0.100 wt.%, the friction coefficient and the wear rate were 0.36 and 6.36 × 10⁻⁶ mm³·N⁻¹·m⁻¹, diminished by 52% and reduced 5.11 times those of pure copper, respectively, while the electrical conductivity rose to 94.57% IACS and the hardness was enhanced by 47.8%. Therefore, this method provides a new approach for the preparation of highly conductive and wear-resistant copper matrix composite materials.

Graphical abstract

Keywords

in-situ synthesis method / copper matrix composite / graphene / tribological property

Cite this article

Download citation ▾

Liangliang Zeng, Yilong Liang, Peng Chen. In-situ grown continuous graphene network enhances the electrical conductivity and tribological properties of copper matrix composites. Front. Mater. Sci., 2024, 18(4): 240704 DOI:10.1007/s11706-024-0704-x

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Bian Y, Ni J, Wang C, . Microstructure and wear characteristics of in-situ micro/nanoscale niobium carbide reinforced copper composites fabricated through powder metallurgy.Materials Characterization, 2021, 172: 110847

[2]	Pratik A, Biswal S K, Haridoss P . Impact of enhanced interfacial strength on physical, mechanical and tribological properties of copper/reduced graphene oxide composites: microstructural investigation.Ceramics International, 2020, 46(14): 22539–22549

[3]	Akbarpour M R, Alipour S, Safarzadeh A, . Wear and friction behavior of self-lubricating hybrid Cu‒(SiC + xCNT) composites.Composites Part B: Engineering, 2019, 158: 92–101

[4]	Huang X, Bao L, Bao R, . Reinforced copper matrix composites with highly dispersed nano size TiC in-situ generated from the carbon polymer dots.Advanced Powder Materials, 2023, 2(2): 100090

[5]	Tan W, Jiang X, Shao Z, . Fabrication and mechanical properties of α-Al₂O₃ whisker reinforced Cu‒graphite matrix composites.Powder Technology, 2020, 375: 124–135

[6]	Chen Z, Fang H C, Zhu J M, , . Effect of carbon type and morphology on the microstructure and properties of carbon/copper composites. Wear, 2020, 460–461: 203473

[7]	Yang G, Wang R, Fang D, . Nano-silver modified carbon nanotubes to reinforce the copper matrix composites and their mechanical properties.Advanced Powder Technology, 2022, 33(8): 103672

[8]	Yang Y, Liu M, Zhou S, . Strengthening behaviour of continuous graphene network in metal matrix composites.Carbon, 2021, 182: 825–836

[9]	Yang T, Chen W, Zhang H, . In-situ generated graphene from wheat flour for enhancing mechanical and electrical properties of copper matrix composites.Materials Science and Engineering A, 2022, 835: 142662

[10]	Wang J, Guo L, Lin W, . The effects of graphene content on the corrosion resistance, and electrical, thermal and mechanical properties of graphene/copper composites.New Carbon Materials, 2019, 34(2): 161–169

[11]	Fathyunes L, Khalil-Allafi J . Characterization and corrosion behavior of graphene oxide–hydroxyapatite composite coating applied by ultrasound-assisted pulse electrodeposition.Ceramics International, 2017, 43(16): 13885–13894

[12]	Zhang C, Tu R, Liu L, . Growth and carrier transport performance of single-crystalline monolayer graphene over electrodeposited copper film on quartz glass.Ceramics International, 2019, 45(18): 24254–24259

[13]	Berman D, Erdemir A, Sumant A V . Graphene: a new emerging lubricant.Materials Today, 2014, 17(1): 31–42

[14]	Liu Y, Liu X, Zhang X, , . Tribological properties and self-lubrication mechanism of in-situ grown graphene reinforced nickel matrix composites in ambient air. Wear, 2022, 496–497: 204308

[15]	Hu Z, Dai R, Wang D, . Preparation of graphene/copper nanocomposites by ball milling followed by pressureless vacuum sintering.New Carbon Materials, 2021, 36(2): 420–428

[16]	Li X H, Yan S J, Chen X, . Microstructure and mechanical properties of graphene-reinforced copper matrix composites prepared by in-situ CVD, ball-milling, and spark plasma sintering.Journal of Alloys and Compounds, 2020, 834: 155182

[17]	Hwang J Y, Lim B K, Tiley J, . Interface analysis of ultra-high strength carbon nanotube/nickel composites processed by molecular level mixing.Carbon, 2013, 57: 282–287

[18]	Lee B, Koo M Y, Jin S H, . Simultaneous strengthening and toughening of reduced graphene oxide/alumina composites fabricated by molecular-level mixing process.Carbon, 2014, 78: 212–219

[19]	Zhang F X, Chu Y Q, Li C S . Fabrication and tribological properties of copper matrix solid self-lubricant composites reinforced with Ni/NbSe₂ composites.Materials, 2019, 12(11): 1854

[20]	Chu K, Wang F, Li Y, . Interface and mechanical/thermal properties of graphene/copper composite with Mo₂C nanoparticles grown on graphene.Composites Part A: Applied Science and Manufacturing, 2018, 109: 267–279

[21]	Qian S Y, Xu Z H, Xie H N, . Effect of rare metal element interfacial modulation in graphene/Cu composite with high strength, high ductility and good electrical conductivity.Applied Surface Science, 2020, 533: 147489

[22]	Lin N M, Liu Q, Zou J J, . Surface damage mitigation of Ti6Al4V alloy via thermal oxidation for oil and gas exploitation application: characterization of the microstructure and evaluation of the surface performance.RSC Advances, 2017, 7(22): 13517–13535

[23]	Zhang X, Liu Y, Liu X, . In-situ grown few-layer graphene reinforced Ni matrix composites with simultaneously enhanced strength and ductility.Materials Science and Engineering A, 2021, 828: 142118

[24]	Wang P, Zhang B, Tan C C, . Microstructural characteristics and mechanical properties of carbon nanotube reinforced Inconel 625 parts fabricated by selective laser melting.Materials & Design, 2016, 112: 290–299

[25]	Yan A, Jiang H, Yu J, . Inhomogeneous copper matrix composites reinforced by RGO/Cu composite foams with high electrical conductivity, tensile strength and fracture elongation.Materials Science and Engineering A, 2023, 867: 144500

[26]	Yang Y, Liang Y, He G, . Graphene core–shell structure guided functionalized interface to prepare high-strength, high-plasticity, and high-conductivity copper matrix composites.Materials Science and Engineering A, 2022, 847: 143349

[27]	Shao G, Liu P, Zhang K, . Mechanical properties of graphene nanoplates reinforced copper matrix composites prepared by electrostatic self-assembly and spark plasma sintering.Materials Science and Engineering A, 2019, 739: 329–334

[28]	Wang G, Zhang Y, Zhang S, . Fabrication of graphene/Cu composites with in-situ grown graphene from solid carbon source.Journal of Materials Research and Technology, 2023, 24: 2372–2384

[29]	Zhang S, Huang P, Wang F . Graphene-boundary strengthening mechanism in Cu/graphene nanocomposites: a molecular dynamics simulation.Materials & Design, 2020, 190: 108555

[30]	Shao G S, Liu P, Li W, . Effects of graphene nanoplates on arc erosion resistance and wear behavior under electric current of copper matrix composites.Journal of Alloys and Compounds, 2020, 829: 154356

[31]	Omran H N, Eivani A R, Farbakhti M, . Tribological properties of copper–graphene (CuG) composite fabricated by accumulative roll bonding.Journal of Materials Research and Technology, 2023, 25: 4650–4657

[32]	Zhao S, Zheng Z, Huang Z X, . Cu matrix composites reinforced with aligned carbon nanotubes: mechanical, electrical and thermal properties.Materials Science and Engineering A, 2016, 675: 82–91

[33]	Dong Z L, Peng Y F, Zhang X H, . Plasma assisted milling treatment for improving mechanical and electrical properties of in-situ grown graphene/copper composites.Composites Communications, 2021, 24: 100619

[34]	Lin G, Peng Y, Li Y, . Remarkable anisotropic wear resistance with 100-fold discrepancy in a copper matrix laminated composite with only 0.2 vol% graphene.Acta Materialia, 2021, 215: 117092

[35]	Liu Q, Castillo-Rodríguez M, Galisteo A J, . Wear behavior of copper–graphite composites processed by field-assisted hot pressing.Journal of Composites Science, 2019, 3(1): 29

[36]	Chen F, Ying J, Wang Y, . Effects of graphene content on the microstructure and properties of copper matrix composites.Carbon, 2016, 96: 836–842

[37]	Rosenkranz A, Costa H L, Baykara M Z, . Synergetic effects of surface texturing and solid lubricants to tailor friction and wear — a review.Tribology International, 2021, 155: 106792