Copper–Carbon Nanotube Composites Enabled by Electrospinning for Advanced Conductors

Copper–Carbon Nanotube Composites Enabled by Electrospinning for Advanced Conductors

The power losses associated with the electrical resistance of copper (Cu) have generated considerable interest in the development of advanced conductors that incorporate carbon nanotubes (CNTs) into the Cu matrixultraconductive Cu (UCC) compositesto increase energy efficiency in various industrial...

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Veröffentlicht in:ACS applied nano materials 2020-07, Vol.3 (7), p.6863-6875
Hauptverfasser: Li, Kai, McGuire, Michael, Lupini, Andrew, Skolrood, Lydia, List, Fred, Ozpineci, Burak, Ozcan, Soydan, Aytug, Tolga
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container_end_page 6875
container_issue 7
container_start_page 6863
container_title ACS applied nano materials
container_volume 3
creator Li, Kai
McGuire, Michael
Lupini, Andrew
Skolrood, Lydia
List, Fred
Ozpineci, Burak
Ozcan, Soydan
Aytug, Tolga
description The power losses associated with the electrical resistance of copper (Cu) have generated considerable interest in the development of advanced conductors that incorporate carbon nanotubes (CNTs) into the Cu matrixultraconductive Cu (UCC) compositesto increase energy efficiency in various industrial and residential applications, ranging from electric power transmission and rotating machinery to electronic devices. To meet this demand, we describe an electrospinning-based polymer nanofiber templating strategy for the fabrication of UCC composites with electrical and mechanical performance exceeding that of Cu. Our approach involves electrospinning of polyvinyl­pyrrolidone (PVP)-based solutions containing CNTs into aligned PVP/CNT nanofibers onto Cu foil substrates, followed by vacuum-assisted thermal removal of organic solvent/polymer from the CNT matrix to achieve a uniformly distributed CNT layer on the Cu surface. Following additional Cu deposition, the Cu–CNT–Cu composites demonstrated similar electrical conductivity, higher current carrying capacity, and improved mechanical properties compared with those obtained from reference Cu. Importantly, after the heat treatment, Raman analysis of the CNT network displayed an increased metallic character that supports the enhanced electrical properties of the UCC composites. Thus, we believe that these performance characteristics together with the commercial viability of the present approach could open new possibilities in designing advanced conductors for a broad range of electrical systems and industrial applications.
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Nano Mater</addtitle><date>2020-07-24</date><risdate>2020</risdate><volume>3</volume><issue>7</issue><spage>6863</spage><epage>6875</epage><pages>6863-6875</pages><issn>2574-0970</issn><eissn>2574-0970</eissn><abstract>The power losses associated with the electrical resistance of copper (Cu) have generated considerable interest in the development of advanced conductors that incorporate carbon nanotubes (CNTs) into the Cu matrixultraconductive Cu (UCC) compositesto increase energy efficiency in various industrial and residential applications, ranging from electric power transmission and rotating machinery to electronic devices. To meet this demand, we describe an electrospinning-based polymer nanofiber templating strategy for the fabrication of UCC composites with electrical and mechanical performance exceeding that of Cu. 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title Copper–Carbon Nanotube Composites Enabled by Electrospinning for Advanced Conductors
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