Simultaneously improved electrical and mechanical performance of hot-extruded bulk scale aluminum-graphene wires
•Addition of reduced graphene oxide nanoparticles to AA1100 improved electrical conductivity by 2.3%.•Yield strength and ultimate tensile strength increased by 30.4% and 6.1%, respectively with graphene addition.•Graphene nanoparticles provided high velocity pathways for energy carriers. Aluminum-ba...
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Published in | Materials science & engineering. B, Solid-state materials for advanced technology Vol. 293; no. C; p. 116452 |
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Main Authors | , , , , , |
Format | Journal Article |
Language | English |
Published |
Netherlands
Elsevier B.V
01.07.2023
Elsevier |
Subjects | |
Online Access | Get full text |
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Summary: | •Addition of reduced graphene oxide nanoparticles to AA1100 improved electrical conductivity by 2.3%.•Yield strength and ultimate tensile strength increased by 30.4% and 6.1%, respectively with graphene addition.•Graphene nanoparticles provided high velocity pathways for energy carriers.
Aluminum-based alloys are highly sought after as lightweight alternatives in electric grid applications. Improving the electrical conductivity of aluminum alloys has the potential to increase the energy efficiency of power transport. The hot extrusion process was used to synthesize AA1100 alloy with low-cost reduced graphene oxide nanoparticles to manufacture ultra-conductive aluminum composites in this study. The effects of graphene content on the electrical and mechanical performance of the composites were evaluated. The macroscale AA1100/graphene wires demonstrated a 2.1% enhancement in electrical conductivity at 20 °C, while the ultimate tensile strength increased by 6.1%. A Zener-Hollomon model was used to confirm the in-process exfoliation of the agglomerated graphene nanoparticle feedstock into high electrical conductivity graphene-like flakes during extrusion. The graphene-like flakes may have provided high-velocity carrier pathways leading to the enhanced electrical performance of the alloy. Transmission electron microscopy at aluminum-graphene interfaces ensures the preclusion of detrimental carbide formation during composite synthesis while confirming the structure of graphene-like flakes. The in-process exfoliation provides an economically viable technique to produce bulk scale “graphinated” aluminum composites for advanced applications and this can also be applied more generally to other alloy systems. |
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Bibliography: | AC06-76LO1830 USDOE Office of Science (SC), Biological and Environmental Research (BER) |
ISSN: | 0921-5107 1873-4944 |
DOI: | 10.1016/j.mseb.2023.116452 |