A thiol and magnetic polymer-based electrochemical sensor for on-site simultaneous detection of lead and copper in water

Wang, Li-Lian; Jiang, Xue; Su, Sha; Rao, Jiantao; Ren, Zixuan; Lei, Ting; Bai, Huiyu

doi:10.1016/j.microc.2021.106493

Cited by 11 publications

(1 citation statement)

References 39 publications

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“…By covalently bonding the sulfhydryl fabric to the innermost PDA@CNT layer, the adhesion between the composite layer and the fabric was greatly improved (As shown in Figure S2, the reaction mechanism is reflected in the Supporting Information.). In the meantime, we utilized the adsorption and reduction properties of PDA for Ag + and an in situ redox reaction technique to construct the Ag-NPs@CNT conductive layer. − Finally, the outermost PDA@CNT was used to protect the Ag-NPs@CNT conducting layer. The created E-Fabric possesses superior and stable electrical qualities, rapid reaction and high-efficiency electric heating properties, superior mechanical qualities, and excellent electromagnetic shielding properties.…”

Section: Introductionmentioning

confidence: 99%

Flexible Wearable Electronic Fabrics with Dual Functions of Efficient EMI Shielding and Electric Heating for Triboelectric Nanogenerators

Wang

Geng³

et al. 2023

ACS Appl. Mater. Interfaces

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Traditional conductive fabrics are prepared by the synthesis of conductive polymers and the coating modification of metals or carbon black conductive materials. However, the conductive fabrics cause a significant decline in performance after washing or mechanical wear, which limits their application. Moreover, the single function of the traditional conductive fabric is also the reason that limits its wide application. In order to prepare a wearable, stable, high-performance, washable, multifunctional conductive fabric, we have carried out related research. In this work, polydopamine was used as a bonding layer, an adsorption reduction layer, and a protective layer to improve the bonding between silver nanoparticles and carbon nanotubes (CNTs) on the polyester fabric surface so as to prepare a multifunctional conductive fabric with a high-stability "sandwich" structure, in which a Ag-NPS@CNT structure acting as an intermediate conductive layer formed on the inner layer PDA@CNT by electroless silver plating and the outermost layer PDA@ CNT coated on the surface of the intermediate conductive layer by the impregnation-drying method. The sheet resistance of an E-Fabric can reach 2.11 Ω/□ due to the uniform and dense conductive path formed by the special structure Ag-NPs@CNT. At a low voltage of 1.5 V, the E-Fabric can reach 117 °C in 50 s and remain stable. The electrical conductivity and current heating properties of the E-Fabric remain good even after multiple washing or bending tests. Due to its stable and outstanding electrical conductivity, the E-Fabric has an electromagnetic shielding efficiency (SE T ) of 35.3 dB in the X-band (8.2−12.4 GHz). In addition, E-Fabricbased spin-coated poly(methyl methacrylate) or polydimethylsiloxane electrodes exhibit excellent performance in nanogenerators. Through the low-frequency friction of the human body, transient voltages up to 4 V can be generated from a 2 cm × 2 cm electrode sample. The output power of a single generator can reach about 12 nW/cm 2 . Therefore, an E-Fabric is considered to have great potential in the fields of electric heating, electromagnetic shielding, and smart wearable devices.

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