• Researchers propose a simple, inexpensiv

    From ScienceDaily@1:317/3 to All on Thursday, March 02, 2023 21:30:22
    Researchers propose a simple, inexpensive approach to fabricating carbon nanotube wiring on plastic films

    Date:
    March 2, 2023
    Source:
    Tokyo University of Science
    Summary:
    Researchers have developed an inexpensive method for fabricating
    multi- walled carbon nanotubes (MWNTs) on a plastic film. The
    proposed method is simple, can be applied under ambient conditions,
    reuses MWNTs, and produces flexible wires of tunable resistances
    without requiring additional steps. It eliminates several drawbacks
    of current fabrication methods, making it useful for large-scale
    manufacturing of carbon wiring for flexible all-carbon devices.


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    FULL STORY ========================================================================== Researchers from Tokyo University of Science in Japan have developed an inexpensive method for fabricating multi-walled carbon nanotubes (MWNTs)
    on a plastic film. The proposed method is simple, can be applied under
    ambient conditions, reuses MWNTs, and produces flexible wires of tunable resistances without requiring additional steps. It eliminates several
    drawbacks of current fabrication methods, making it useful for large-scale manufacturing of carbon wiring for flexible all-carbon devices.


    ========================================================================== Carbon nanotubes (CNTs) are cylindrical tube-like structures made
    of carbon atoms that display highly desirable physical properties
    like high strength, low weight, and excellent thermal and electrical conductivities. This makes them ideal materials for various applications, including reinforcement materials, energy storage and conversion
    devices, and electronics. Despite such immense potential, however,
    there have been challenges in commercializing CNTs, such as their
    incorporation on plastic substrates for fabricating flexible CNT-based
    devices. Traditional fabrication methods require carefully controlled environments such as high temperatures and a clean room. Further, they
    require repeat transfers to produce CNTs with different resistance values.

    More direct methods such as laser-induced forward transfer (LIFT) and
    thermal fusion (TF) have been developed as alternatives. In the LIFT
    method, a laser is used to directly transfer CNTs onto substrates, while
    in TF, CNTs are mixed with polymers that are then selectively removed
    by a laser to form CNT wires with varying resistance values. However,
    both these methods are expensive and have their unique problems. LIFT
    requires expensive pulsed lasers and preparation of CNTs with specific resistance values, while TF uses large amounts of CNTs that are not
    utilized and go to waste.

    Aiming to develop a more simple and inexpensive approach, Associate
    Professor Dr. Takashi Ikuno along with his collaborators, Mr. Hiroaki
    Komatsu, Mr. Yosuke Sugita and Mr. Takahiro Matsunami at Tokyo
    University of Science, Japan, recently proposed a novel method that
    enables fabrication of multi-walled CNT (MWNT) wiring on a plastic film
    under ambient conditions (room temperature and atmospheric pressure)
    using a low-cost laser.

    The breakthrough, published in the journal Scientific Reports on 08
    February 2023, involves coating a polypropylene (PP) film with an MWNT
    film about 10 mm thick and then exposing it to a mW UV laser. The result
    is a conductive wiring made of a combination of MWNT and PP.

    "This process enables the easy 'drawing' of wiring and flexible devices
    for wearable sensors without the need for complex processes," highlights
    Dr. Ikuno.

    The researchers attributed the formation of these wires to the difference
    in the thermal conductivities between the MWNT and the PP film. As the
    MWNT/PP film is exposed to the laser, the high thermal conductivity
    of the MWNT layer causes the heat to spread along the length of the
    wire, resulting in high temperatures at the MWNT-PP interface and lower temperatures elsewhere in the PP film. Directly below the laser, where temperatures are the highest, the PP diffuses into the MWNT film to form
    a thick PP/MWNT composite, while a thin PP/ MWNT layer is formed at the
    edges of the laser where temperatures are relatively low.

    The proposed method also allows the fabrication of carbon wires with
    different resistance values within the same process (without repeat
    transfer) by simply changing the irradiation conditions, thereby
    eliminating the need for additional steps. Exposing the PP/MWNT film
    to high laser energies, achieved either by low scanning speeds, a high
    number of laser exposures, or the use of a high-powered laser, produces
    thicker wires with a higher concentration of MWNTs. Consequently, the
    lower resistivity of MWNT and the thicker wire lowers the resistance
    per unit length of the wire (resistance is directly proportional to the
    ratio between the resistivity and the thickness of the wire).

    By precisely controlling the exposure of the MWNT/PP film to laser
    light, the researchers successfully fabricated MWNT wires with a wide
    range of resistance values, from 0.789 kO/cm to 114 kO/cm. Moreover,
    these wires were highly flexible and maintained their resistance even
    when bent repeatedly.

    Additionally, the method solved one of the pressing issues with current techniques, namely the inability of LIFT and TF techniques to reuse
    CNTs not utilized in the fabrication process. In the proposed method,
    MWNTs not incorporated into the PP film during laser irradiation can be recovered and reused, allowing for the creation of new MWNT wires with
    little to no change in resistance values.

    With its simplicity, efficient utilization of CNTs, and the capability
    to create high-quality wires, the new method has the potential to realize large- scale manufacturing of flexible carbon wiring for flexible sensors
    and energy conversion and storage devices.

    "We expect the process cost to be significantly reduced compared to
    that for conventional methods. This, in turn, will contribute to the realization of low- cost flexible sensors that are expected to have wide applications in large quantities," concludes Dr. Ikuno.

    * RELATED_TOPICS
    o Matter_&_Energy
    # Optics # Electronics # Graphene # Detectors #
    Wearable_Technology # Thermodynamics # Chemistry # Physics
    * RELATED_TERMS
    o Carbon_nanotube o Carbon-14 o Hydrocarbon o Carbon_dioxide
    o Carbon_monoxide o Silicon o Fullerene o Radiocarbon_dating

    ========================================================================== Story Source: Materials provided by Tokyo_University_of_Science. Note:
    Content may be edited for style and length.


    ========================================================================== Journal Reference:
    1. Hiroaki Komatsu, Takahiro Matsunami, Yosuke Sugita, Takashi
    Ikuno. Direct
    formation of carbon nanotube wiring with controlled electrical
    resistance on plastic films. Scientific Reports, 2023; 13 (1) DOI:
    10.1038/s41598- 023-29578-w ==========================================================================

    Link to news story: https://www.sciencedaily.com/releases/2023/03/230302093402.htm

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