The development of modern electronics
has raised great demand for
multifunctional materials to protect electronic instruments against
electromagnetic interference (EMI) radiation and ice accretion in
cold weather. However, it is still a great challenge to prepare high-performance
multifunctional films with excellent flexibilty, mechanical strength,
and durability. Here, we propose a layer-by-layer assembly of cellulose
nanofiber (CNF)/Ti3C2T
x
nanocomposites (TM) on a bacterial cellulose (BC) substrate via repeated spray coating. CNFs are hybridized with Ti3C2T
x
nanoflakes to
improve the mechanical properties of the functional coating layer
and its adhesion with the BC substrate. The densely packed hierarchical
structure and strong interfacial interactions endows the TM/BC films
with good flexibility, ultrahigh mechanical strength (>250 MPa),
and
desirable toughness (>20 MJ cm–3). Furthermore,
benefiting from the densely packed hierarchical structure, the resultant
TM/BC films present outstanding EMI shielding effictiveness of 60
dB and efficient electro-/photothermal heating performance. Silicone
encapsulation further imparts high hydrophobicity and exceptional
durability against solutions and deformations to the multifunctional
films. Impressively, the silicone-coated TM/BC film (Si-TM/BC) exhibits
desirable low voltage-driven Joule heating and excellent photoresponsive
heating performance, which demonstrates great feasibility for efficient
thermal deicing under actual conditions. Therefore, we believe that
the Si-TM/BC film with excellent mechanical properties and durability
holds great promise for the practical applications of EMI shielding
and ice accretion elimination.
A cephalopod-inspired mechanoluminescence material with skin-like self-healing and sensing properties was developed by the construction of a unique strain-dependent microcrack-structured conductive UV-shielding layer upon a self-healable supramolecular fluorescent elastomer with synergistic dynamic crosslinking network design.
Antibacterial hydrogels have been intensively studied due to their wide practical potential in wound healing. However, developing an antibacterial hydrogel that is able to integrate with exceptional mechanical properties, cell affinity, and adhesiveness will remain a major challenge. Herein, a novel hydrogel with antibacterial and superior biocompatibility properties was developed using aluminum ions (Al 3+ ) and alginate− dopamine (Alg-DA) chains to cross-link with the copolymer chains of acrylamide and acrylic acid (PAM) via triple dynamic noncovalent interactions, including coordination, electrostatic interaction, and hydrogen bonding. The cationized nanofibrillated cellulose (CATNFC), which was synthesized by the grafting of long-chain quaternary ammonium salts onto nanofibrillated cellulose (NFC), was utilized innovatively in the preparation of antibacterial hydrogels. Meanwhile, alginate-modified dopamine (Alg-DA) was prepared from dopamine (DA) and alginate. Within the hydrogel, the catechol groups of Alg-DA provided a decent fibroblast cell adhesion to the hydrogel. Additionally, the multitype cross-linking structure within the hydrogel rendered the outstanding mechanical properties, self-healing ability, and recycling in pollution-free ways. The antibacterial test in vitro, cell affinity, and wound healing proved that the as-prepared hydrogel was a potential material with all-around performances in both preventing bacterial infection and promoting tissue regeneration during wound healing processes.
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