MXene Functionalized Kevlar Yarn via Automated, Continuous Dip Coating

The rise of the Internet of Things has spurred extensive research on integrating conductive materials into textiles to turn them into sensors, antennas, energy storage devices, and heaters. MXenes, owing to their high electrical conductivity and solution processability, offer an efficient way to add...

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Bibliographic Details
Published in:Advanced functional materials 2024-04, Vol.34 (14), p.n/a
Main Authors: Bi, Lingyi, Perry, William, Wang, Ruocun (John), Lord, Robert, Hryhorchuk, Tetiana, Inman, Alex, Gogotsi, Oleksiy, Balitskiy, Vitaliy, Zahorodna, Veronika, Baginskiy, Ivan, Vorotilo, Stepan, Gogotsi, Yury
Format: Article
Language:English
Subjects:
Aramid fibers
Automation
dip coating
Electrical resistivity
Energy storage
Immersion coating
Internet of Things
Kevlar (trademark)
Mechanical properties
multifunctional yarns
MXene
MXenes
Ohmic dissipation
Resistance heating
smart composites
smart textiles
strain sensing
Textiles
Yarn
Yarns
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Summary:The rise of the Internet of Things has spurred extensive research on integrating conductive materials into textiles to turn them into sensors, antennas, energy storage devices, and heaters. MXenes, owing to their high electrical conductivity and solution processability, offer an efficient way to add conductivity and electronic functions to textiles through simple dip coating. However, manual development of MXene‐coated textiles restricts their quality, quantity, and variety. Here, a versatile automated yarn dip coater tailored for producing continuously high‐quality MXene‐coated yarns and conducted the most comprehensive MXene‐yarn dip coating study to date is developed. Compared to manual methods, the automated coater provides lower resistance, superior uniformity, faster speed, and reduced MXene consumption. It also enables rapid coating parameter optimization, resulting in a thin Ti3C2 coating uniform over a 1 km length on a braided Kevlar yarn while preserving its excellent mechanical properties (over 800 MPa) and adding Joule heating and damage sensing to composites reinforced by the yarns. By dip‐coating five different yarns of varying materials, diameters, structures, and chemistries, new insights into MXene‐yarn interactions are gained. Thus, the automated dip coating presents ample opportunities for scalable integration of MXenes into a wide range of yarns for diverse functions and applications. The IoT's growth fuels research on MXene integration into textiles. The automated yarn dip coater exceeds manual methods, providing lower resistance, superior uniformity, faster speed, and reduced MXene consumption across multiple yarns. It swiftly optimizes coatings for specific applications, demonstrated on a braided Kevlar yarn for Joule heating and strain sensing in composites.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202312434