Abstract
In the present investigation the possibility of using exfoliated graphite nanoplatelets (xGnP) as reinforcement in order to enhance the mechanical properties of Cu-based metal matrix composites is explored. Cu-based metal matrix composites reinforced with different amounts of xGnP were fabricated by powder metallurgy route. The microstructure, sliding wear behaviour and mechanical properties of the Cu-xGnP composites were investigated. xGnP has been synthesized from the graphite intercalation compounds (GIC) through rapid evaporation of the intercalant at an elevated temperature. The thermally exfoliated graphite was later sonicated for a period of 5 h in acetone in order to achieve further exfoliation. The xGnP synthesized was characterized using SEM, HRTEM, X-ray diffraction, Raman spectroscopy and Fourier transform infrared spectroscopy. The Cu and xGnP powder mixtures were consolidated under a load of 565 MPa followed by sintering at 850°C for 2 h in inert atmosphere. Cu-1, 2, 3 and 5 wt% xGnP composites were developed. Results of the wear test show that there is a significant improvement in the wear resistance of the composites up to addition of 2 wt% of xGnP. Hardness, tensile strength and strain at failure of the various Cu-xGnP composites also show improvement upto the addition of 2 wt% xGnP beyond which there is a decrease in these properties. The density of the composites decreases with the addition of higher wt% of xGnP although addition of higher wt% of xGnP leads to higher sinterability and densification of the composites, resulting in higher relative density values. The nature of fracture in the pure Cu as well as the various Cu-xGnP composites was found to be ductile. Nanoplatelets of graphite were found firmly embedded in the Cu matrix in case of Cu-xGnP composites containing low wt% of xGnP.
Highlights
Over the last several decades, there has been a considerable interest in the use of Cu-based metal matrix composites (MMCs)
In the case of xGnP the increased exfoliation achieved by the thermal exfoliation of the graphite intercalation compounds (GIC) followed by sonication in acetone in order to achieve further exfoliation has led to the reduction in the intensity of the (002) peak
The less intensity of the (002) peak in the case of xGnP clearly indicates that the as-received natural flake graphite (NFG) has been exfoliated [15] [16]
Summary
Over the last several decades, there has been a considerable interest in the use of Cu-based metal matrix composites (MMCs). Graphene is a two-dimensional platelet made of carbon atoms It is a one atom thick material and is a promising nanofiller that could improve the mechanical, electrical and thermal properties of the composites. Its excellent mechanical properties make it an ideal reinforcement for developing nanocomposites It has a modulus of elasticity of 1 TPa and a fracture strength is 125 GPa. The electrical resistivity of graphene is 10−6 Ω∙cm and its thermal conductivity is ~3080 - 5300 W/m∙K. Exfoliated graphite nanoplatelets (xGnP) could be an attractive reinforcement material for Cu-based metal matrix composites due to its high strength and elastic modulus. An important factor in producing xGnP is its low cost and the ease with which it can be produced This makes the development of nanocomposites reinforced with xGnP very feasible. The xGnP developed was used as reinforcement in Cu-based metal matrix composites. Effects of addition of xGnP on the morphology and the mechanical, tribological and fracture behavior of Cu-xGnP composites have been investigated
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