Carbon Nanotube Coated Conductors

Holesinger, T. G.; DePaula, R.F.; Papin, Pallas A.; Rowley, John; Schneider, Matthew M.; Khanbolouki, Pouria; Tehrani, Mehran

doi:10.1021/acsaelm.9b00356

Cited by 7 publications

(14 citation statements)

References 42 publications

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“…A carbon-metal composite is a promi sing alternative to conventional Cu/Al wires due to their improved current-carrying capability and enhanced chemical resistance. [5][6][7] Nano/microscale carbon materials, e.g., carbon nanotubes and graphene flakes, have been mixed within a metal matrix to develop effective carbon-metal composites for electrical applications. The general goal for these approaches [4,8] is to integrate the thermoelectrical advantages of carbon constituents, namely excellent current density limit (>10 8 A cm -2 ), electron mobility (15 000 cm 2 V -1 s -1 ), and thermal conductivity (≈5000 W m -1 K -1 ), with metals that have high charge-carrier density (8.491 × 10 28 carriers m -3 for Cu) for advanced power transmission.…”

Section: Doi: 101002/adma202104208mentioning

confidence: 99%

“…Efforts have been put forth to incorporate a continuous graphene sheet as a conductive shell on a microscale Cu wire to improve electrical conductivity and oxidation resistance of the carbon-shell-Cu-core composite structure, e.g., 10% improvement is observed in carbon nanotube-coated, 1 mm-diameter Cu wires. [6] However, the fundamental mechanisms of the coupled thermal and electrical behavior of axially continuous graphene-copper composites at the microscale are not yet fully understood unlike nanoscale carbon-metal composites. [24][25][26][27] In this regard, we develop the axially continuous graphenecopper (ACGC) composite wires using microscale Cu wires with diameters ranging from 10 to 80 µm.…”

Section: Introductionmentioning

confidence: 99%

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An Axially Continuous Graphene–Copper Wire for High‐Power Transmission: Thermoelectrical Characterization and Mechanisms

et al. 2021

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The demand for high‐power electrical transmission continues to increase with technical advances in electric vehicles, unmanned drones, portable devices, and deployable military applications. In this study, significantly enhanced electrical properties (i.e., a 450% increase in the current density breakdown limit) are demonstrated by synthesizing axially continuous graphene layers on microscale‐diameter wires. To elucidate the underlying mechanisms of the observed enhancements, the electrical properties of pure copper wires and axially continuous graphene–copper (ACGC) wires with three different diameters are characterized while controlling the experimental conditions, including ambient temperature, gases, and pressure. The study reveals that the main mechanism that allows the application of extremely large current densities (>400 000 A cm−2) through the ACGC wires is threefold: the continuous graphene layers considerably improve: 1) surface heat dissipation (224% higher), 2) electrical conductivity (41% higher), and 3) thermal stability (41.2% lower resistivity after thermal cycles up to 450 °C), compared with pure copper wires. In addition, it is observed, through the use of high‐speed camera images, that the ACGC wires exhibit very different failure behavior near the current density limit, compared with the pure copper wires.

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Section: Doi: 101002/adma202104208mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An Axially Continuous Graphene–Copper Wire for High‐Power Transmission: Thermoelectrical Characterization and Mechanisms

et al. 2021

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“…Polymeric materials are widely used as flexible substrates for flexible sensors due to their excellent flexibility, good thermal stability, and chemical stability, for example, polydimethylsiloxane (PDMS), , Ecoflex, − polyurethane (PU), , polyethylene terephthalate (PET), , polyimide (PI), , rubber, , and so on. Conductive filled materials, such as carbon nanotubes (CNTs), − graphene (including rGO), ,,− metal nanoparticles and nanowires, − conductive polymers, and so on have been intensively studied in recent years. Using the conductive filled nanoparticles, a high sensitivity of sensors was reported to be easy to achieve.…”

Section: Carbon-based Materials and Sensor Manufacturing Methodsmentioning

confidence: 99%

Recent Advances of Carbon-Based Flexible Strain Sensors in Physiological Signal Monitoring

Xiao

et al. 2020

ACS Appl. Electron. Mater.

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Flexible strain sensors have attracted much attention due to their good flexibility, high sensitivity, superior repeatability, and great potentials for application in physiological signal detection. Carbon materials, including carbon nanotubes, graphene, carbon black, graphite, and natural-bioderived carbon materials are often used as active materials for the fabrication of flexible strain sensors because of their superior electrical conductivity and flexibility. Among them, carbon nanotubes and graphene can be prepared into flexible sensors in various forms, such as fibers, films, or textiles. Therefore, carbon material flexible sensors used for physiological signal detection have been sufficiently studied. Herein, the sensing mechanism of flexible strain sensors and the recent advances are reviewed. Sensor characteristics and functions of fibers/films with carbon nanotubes, graphene, and other carbon materials are described in terms of materials, preparation, and properties. From the aspect of sensor application, the sensors with different materials in large- and small-amplitude physiological signals are introduced in detail. Eventually, the superiorities and disadvantages of various carbon-based flexible strain sensors are summarized, and the challenges and opportunities of them in the future are also presented.

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“…Novel approaches for fabricating CNT conductor wires have been also investigated. [29,30] In general, electrical conductivity of CNT fibers can be improved by up to ten times via acid, [31] iodine, [32] or metal nanoparticle [24] doping. Doped nanocarbon fibers contain only a few weight percent of a metal or metal halide, [18] in contrast to metal-carbon nanocomposites that are largely metal-based.…”

Section: Carbonaceous Conductorsmentioning

confidence: 99%

“…Specific conductivity is σ / ρ = ( L / RA )/( M / LA ), which can be simplified to σ / ρ = ( L 2 / RM ). [ 29 ]…”

Section: Electrical Conductorsmentioning

confidence: 99%

Advanced Electrical Conductors: An Overview and Prospects of Metal Nanocomposite and Nanocarbon Based Conductors

Tehrani

2021

Physica Status Solidi (a)

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Advanced electrical conductors that outperform copper and aluminum can revolutionize our lives by enabling billions of dollars in energy savings and facilitating a transition to an electric mobility future. Nanocarbons (carbon nanotubes and graphene) present a unique opportunity for developing advanced conductors for electrical power, communications, electronics, and electric machines for the defense, energy, and automotive industries. Herein, the major research progress in the field of advanced nanocarbon-based and metalnanocarbon conductors is compiled. The benefits and drawbacks of advanced conductors are also elucidated with respect to conventional ones and their materials science, mechanical and physical properties, and characterization are discussed. Finally, several areas of future research for advanced electrical conductors are proposed.

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Carbon Nanotube Coated Conductors

Cited by 7 publications

References 42 publications

An Axially Continuous Graphene–Copper Wire for High‐Power Transmission: Thermoelectrical Characterization and Mechanisms

An Axially Continuous Graphene–Copper Wire for High‐Power Transmission: Thermoelectrical Characterization and Mechanisms

Recent Advances of Carbon-Based Flexible Strain Sensors in Physiological Signal Monitoring

Advanced Electrical Conductors: An Overview and Prospects of Metal Nanocomposite and Nanocarbon Based Conductors

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