Multifunctional Filler‐Free PEDOT:PSS Hydrogels with Ultrahigh Electrical Conductivity Induced by Lewis‐Acid‐Promoted Ion Exchange

Abstract: Highly conductive hydrogels with biotissue‐like mechanical properties are of great interest in the emerging field of hydrogel bioelectronics due to their good biocompatibility, deformability, and stability. Fully polymeric hydrogels may exhibit comparable Young's modulus to biotissues. However, most of these filler‐free hydrogels have a low electrical conductivity of <10 S cm−1, which limits their wide applications of them in digital circuits or bioelectronic devices. In this work, a series of metal‐halides… Show more

“…The SH-side exhibited a contact angle of 135 °, signi cantly higher than the eshy surface layer, attributed to the introduction of superhydrophobic materials during the preparation process and the surface's rough structure. [49][50][51][52][53][54][55] The inset in the gure shows an optical photograph of SHRC-skin immersed in water, where magni ed images revealed numerous small water droplets formed on the SH-side, con rming its outstanding hydrophobicity. Additional drops of liquid on the SH-side demonstrated the presence of intact and unabsorbed small droplets (Fig.…”

Nano-Engineered Versatile Janus Natural-Skin with Sandwich Structure for Wearable All-Season Personal Thermal Management

“…The SH-side exhibited a contact angle of 135 °, signi cantly higher than the eshy surface layer, attributed to the introduction of superhydrophobic materials during the preparation process and the surface's rough structure. [49][50][51][52][53][54][55] The inset in the gure shows an optical photograph of SHRC-skin immersed in water, where magni ed images revealed numerous small water droplets formed on the SH-side, con rming its outstanding hydrophobicity. Additional drops of liquid on the SH-side demonstrated the presence of intact and unabsorbed small droplets (Fig.…”

Nano-Engineered Versatile Janus Natural-Skin with Sandwich Structure for Wearable All-Season Personal Thermal Management

“…37–46 Big progress has been achieved in inorganic TE materials in the past years. 47–64 He et al enhanced the ZT to 2.7 at 750 K in germanium telluride-based high-entropy materials and realized a high experimental conversion efficiency of 13.3% by high-entropy concept tuning electron and phonon decoupling. 53 Zhao and coworkers developed a lattice plainification strategy for defect engineering to weaken defect scattering and boost carrier mobility, leading to a ZT of ∼1.5 at 300 K. 54 However, traditional inorganic TE materials are often composed of transition metals, such as Pb, Te, Bi, etc.…”

Recent advances of 2D conductive metal–organic frameworks in thermoelectrics

“…Recently, gels have emerged as the optimal foundation for the fabrication of high-performance EMI shielding materials. 20–23 Gels represent intricate three-dimensional (3D) polymer networks adept at retaining substantial quantities of liquids while upholding their hierarchical 3D structures. 24–26 Gels typically possess commendable mechanical flexibility, elasticity, and noteworthy biological attributes, rendering them highly promising for providing electromagnetic radiation protection in the realm of adaptable and wearable electronics.…”

Controllable proton-reservoir ordered gel towards reversible switching and reliable electromagnetic interference shielding