Copper-Coated Graphene Nanoplatelets-Reinforced Al-Si Alloy Matrix Composites Fabricated by Stir Casting Method

doi:10.1007/s40195-020-01112-1

Abstract

Abstract:

In this study, Cu nanoparticles-coated graphene nanoplatelets (Cu-NPs@GNPs) were synthesized by a simple in situ method with the assistance of NaCl templates and used for reinforcing Al-10Si composites through stir casting process. The experimental results showed that the coating of Cu-NPs on the GNPs could compromise the density mismatch between GNPs and metal matrix and effectively hinder the float of GNPs during stirring. The reaction of Cu-NPs and Al matrix could protect the structural integrity of GNPs as well as improve the interfacial wettability between GNPs and the matrix, thus promoting the uniform dispersion of GNPs in the composites. As a result, the as-prepared 0.5 wt% Cu-NPs@GNPs/Al-10Si composite exhibited a tensile strength of 251 MPa (45% higher than the Al-10Si) with a total elongation of 15%. The strengthening effects were mainly attributed to the following three reasons: Firstly, the Cu-NPs coating improved the interfacial bonding between GNPs and Al matrix which promoted the load transfer from the matrix to the GNPs. Secondly, the nanoscale Al₂Cu formed by the reaction of Cu-NPs and Al matrix played a role in precipitation strengthening. Thirdly, GNPs refined the silicon phases and improved the monolithic performances of the composites.

Key words: Al-Si alloy, Graphene, Stir casting, Wettability, Si phase refinement

Xiaoqi Han, Lizhuang Yang, Naiqin Zhao, Chunnian He. Copper-Coated Graphene Nanoplatelets-Reinforced Al-Si Alloy Matrix Composites Fabricated by Stir Casting Method[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(1): 111-124.

Figures/Tables 10

Fig. 1 Schematic illustration of the in situ catalytic synthesis and stir casting-hot rolling process for the fabrication of Cu-NPs@GNPs/Al-10Si composites

Fig. 2 a SEM image of spherical precursor powder. b, c SEM and high-resolution SEM images of Cu-NPs@GNPs. d TEM image of Cu-NPs distributed on GNPs. High-resolution TEM image of e graphene layers, f a typical Cu-NP

Fig. 3 a XRD pattern of in situ synthesized Cu-NPs@GNPs. b Raman spectrum of in situ synthesized Cu-NPs@GNPs and pure GNPs before and after ball milling process. c TGA and DTA profile of in situ synthesized Cu-NPs@GNPs

Fig. 4 SEM images of a, b 180 r-120 min ball milled 2.5 wt% Cu-NPs@GNPs/Al powders, c, d 180 r-120 min and 360 r-90 min ball milled Cu-NPs@GNPs/Al powders, e, f 180 r-120 min and 360 r-90 min ball milled mixture of (Cu-NPs + GNPs)/Al powders

Fig. 5 Si morphologies of Al-10Si and composites reinforced by Cu-NPs@GNPs: a modified Al-10Si, b, c modified 0.3 and 0.5 wt% Cu-NPs@GNPs/Al-10Si, d unmodified Al-10Si, e, f unmodified 0.3 and 0.5 wt% Cu-NPs@GNPs/Al-10Si

Fig. 6 Si morphologies of a modified Al-10Si, b modified 0.5 wt% (ex situ Cu-NPs/GNPs)/Al-10Si composite, c modified 0.195 wt% (Cu-NPs)/Al-10Si composite, d modified 0.325 wt% (Cu-NPs)/Al-10Si composite

Fig. 7 Raman results of the 1.0 wt% (Cu-NPs@GNPs)/Al-10Si bulk sample. a Optical image from the sample showing the scanned area of 20 μm × 20 μm outlined by white square. b Raman spectrum of some points from the map. c D-band intensity. d G-band intensity

Fig. 8 HRTEM images of microstructure in 0.5 wt% Cu-NPs@GNPs/Al-10Si composite: a GNPs and Al2Cu, b, c GNPs, d Al2Cu in the aluminum grain boundary, e, f Al2Cu in the aluminum crystal

Fig. 9 Elemental mapping images of 0.5 wt% Cu-NPs@GNPs/Al-10Si: a Al2Cu in the aluminum matrix, b-d Al, Cu, Si elements distribution in (a), e Al2Cu at the Al-Si interface, f-h Al, Cu, Si elements distribution in (e)

Fig. 10 Stress-strain curves of a Al-10Si and composites reinforced by various content of Cu-NPs@GNPs, b Al-10Si and composites reinforced by various content of Cu-NPs, c composites reinforced by Cu-NPs, mixture of Cu-NPs and GNPs, ex situ Cu-NPs/GNPs and in situ synthesized Cu-NPs@GNPs. d Comparison of strengthening efficiency and total elongation related to reinforcement contents of metal composites reinforced by different types of reinforcement fabricated by stir casting method

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