激光烧蚀法制备纺织基ti3c2mxene电容器。

IF 3.1 4区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

ChemistryOpen Pub Date : 2025-08-05 DOI:10.1002/open.202500253

Eugenio Gibertini, Ali Gokhan Demir, Riccardo Cesaro, Prisca Viviani, Luca Magagnin

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引用次数: 0

摘要

电子纺织品技术正在迅速发展，但电源仍然是限制因素之一，特别是对于那些集成到纺织品中的技术。目前迫切需要能够储存和供应能量的柔性纺织微设备。在这项工作中，证明了激光烧蚀（LA）可以方便地用于在tpu涂层棉织物上实现具有交叉构型的图像化薄膜电极，以生产基于纺织品的储能单元。即，通过LA对Ti3C2 MXene （MX）电极进行图图化，并涂覆一层基于LiCl的紫外光固化凝胶聚合物电解质，以生产基于纺织品的柔性对称电容器。还表明，应仔细设计LA过程，以防止电极在过程本身中降解。基于纺织品的MX对称电容器（MX Sy-Cs）的电容随扫描速率的变化范围为11.7 mF cm-2至0.53 mF cm-2。在100µA cm-2电流下循环9025次，平均电容为2.03 mF cm-2, C/C0 = 0.8。此外，一系列基于纺织品的MX sy - c被证明与低功率纺织品储能应用兼容。

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Textile-Based Ti3C2 MXene Capacitor by Laser Ablation Patterning.

E-textile technologies are quickly advancing, but the power supply is still one of the limiting factors, particularly for those integrated into textiles. There is a pressing demand for flexible textile-based microdevices capable of storing and supplying energy. In this work, it is demonstrated that laser ablation (LA) can be conveniently used to achieve patterned thin film electrodes with interdigitated configuration on TPU-coated cotton fabric to produce textile-based energy storage units. Namely, Ti3C2 MXene (MX) electrodes were patterned via LA and coated with a LiCl based UV-curable gel polymer electrolyte to produce a textile-based flexible symmetrical capacitor. It is also shown that the LA process should be carefully designed to prevent electrode degradation during the process itself. The capacitance of textile-based MX symmetrical capacitors (MX Sy-Cs) ranged from 11.7 mF cm^-2 to 0.53 mF cm^-2 depending on the scan rate. By galvanostatic cycling at 100 µA cm^-2, the average capacitance was 2.03 mF cm^-2 with the C/C₀ = 0.8 condition found after 9025 cycles. Moreover, an array of textile-based MX Sy-Cs is demonstrated to be compatible with low power textile energy storage applications.

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来源期刊

ChemistryOpen CHEMISTRY, MULTIDISCIPLINARY-

CiteScore

4.80

自引率

4.30%

发文量

143

审稿时长

1 months

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