Journal
CHEMICAL ENGINEERING JOURNAL
Volume 454, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.cej.2022.140150
Keywords
Janus bond-mediated layer-by-layer assembly; Ni textile; TOA-CuxS nanoparticle
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This study presents a high-performance textile-based energy storage electrode, which effectively incorporates conductive and electrochemically active components into insulating textiles. The electrode exhibits mechanical flexibility, large surface area, low resistance, uniform fibril structure, and high capacitance and operational stability.
One of the most critical issues in developing high-performance textile-based energy storage (TES) electrodes is to effectively incorporate conductive and electrochemically active components into insulating textiles, maintaining the high mechanical flexibility and large surface area of pristine textiles. Herein, we report a high-performance TES electrode prepared from a Janus bond assembly of nonnoble metal-based nanoparticles (NPs) and subsequent electrodeposition. First, tetraoctylammonium-stabilized copper sulfide NPs (TOA-CuxS NPs) with a diameter of similar to 10 nm were synthesized in organic media, which were Janus bond layer-by-layer (JB LbL)assembled with cysteamine (CA) linkers onto cotton textiles. In this case, CA linkers directly and robustly bridged all the interfaces between the OH-functionalized textile and CuxS NPs as well as between neighboring CuxS NPs. Additionally, the JB LbL-assembled CuxS NPs perfectly converted the insulating textile to a conductive textile with a uniform fibril structure and oxidation stability. For the preparation of pseudocapacitive textiles, the subsequent Ni electrodeposition was further carried out onto the conductive and hydrophilic (TOA-CuxS NP/CA)(n) multilayer-coated textile. The formed TES electrodes exhibited a low sheet resistance of 0.03 Omega sq(-1 ), a highly uniform fibril structure, a considerably high areal capacitance of 2.56 F cm(-2) (at 3 mA cm(-2) ), and high operational stability (i.e., capacity retention of 88.6 % after 10,000 cycles).
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