Qiuyan Duan scite author profile

Although flexible textile-based electronics and lightweight electromagnetic shielding materials have attracted increasing attention due to their wide application, the seamless integration of textile sensors and electromagnetic shielding materials is still a challenge. Herein, we designed a simple, cost-effective, and environmentally friendly method to fabricate nickel-plated acetate fabrics coated with carbon nanotubes, using silk sericin to disperse carbon nanotubes in water and adsorb abundant nickel ions easily on the surface of carbon nanotubes via hydroxyl groups without other additives. The as-prepared composites exhibited excellent conductivity and electromagnetic interference (EMI) shield effectiveness (>30 dB) at X-band with around 0.8 mm thickness. The low-loading carbon nanotubes could offer more loss mechanism and had a positive effect upon EMI. The conductive textiles had higher tensile strength and negative relative resistance changes in strain, and had a great potential as wearable sensors in response to finger folding and wrist bending. Silk sericin as a green adhesive and dispersant provides an alternative strategy to large-scale produce multifunctional conductive wearable textiles for applications in EMI shielding and/or human-machine interaction.

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Highly Dispersed, Adhesive Carbon Nanotube Ink for Strain and Pressure Sensors

Duan

Lan

2022

ACS Appl. Mater. Interfaces

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Carbon nanotubes (CNT) with prominent electrical and mechanical properties are ideal candidates for flexible wearable devices. However, their poor dispersity in solvents greatly limits their applications as a conductive ink in the fabrication of wearable sensors. Herein, we demonstrate a kind of CNT-based conductive dispersion with high dispersity and adhesiveness using cellulose derivatives as the solvent, in which γ-aminopropyl triethoxy silane as a cross-linking agent reacts with cellulose to form copolymer networks, and simultaneously it also acts as an initiator to induce the self-polymerization of dopamine. Based on the conductive CNT ink, we also demonstrated textile-based strain sensors by stencil printing and sponge-based pressure sensors by the dipping method. The textile-based strain sensors could respond to external stimuli promptly. Then, the strain sensors were encapsulated via polydimethylsiloxane with the expansion of working ranges from less than 20 to nearly 70%. The encapsulated textile sensors exhibited excellent sensing performance as wearable strain sensors to monitor human motions including smile, throat vibration, finger folding, wrist bending, and elbow twisting. The sponge sensors hold high sensitivity and excellent durability as well. The conductive CNT-based ink provides an alternative idea in the development of flexible wearable devices.

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Atomically dispersed palladium-based catalysts obtained via constructing a spatial structure with high performance for lean methane combustion

et al. 2020

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Qiuyan Duan

Hydroxyl groups attached to Co²⁺ on the surface of Co₃O₄: a promising structure for propane catalytic oxidation

Silk Sericin As a Green Adhesive to Fabricate a Textile Strain Sensor with Excellent Electromagnetic Shielding Performance

Highly Dispersed, Adhesive Carbon Nanotube Ink for Strain and Pressure Sensors

Atomically dispersed palladium-based catalysts obtained via constructing a spatial structure with high performance for lean methane combustion

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Qiuyan Duan

Hydroxyl groups attached to Co2+ on the surface of Co3O4: a promising structure for propane catalytic oxidation

Silk Sericin As a Green Adhesive to Fabricate a Textile Strain Sensor with Excellent Electromagnetic Shielding Performance

Highly Dispersed, Adhesive Carbon Nanotube Ink for Strain and Pressure Sensors

Atomically dispersed palladium-based catalysts obtained via constructing a spatial structure with high performance for lean methane combustion

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Hydroxyl groups attached to Co²⁺ on the surface of Co₃O₄: a promising structure for propane catalytic oxidation