TENG-driven single-droplet green electrochemical etching and deposition for chemical sensing applications

IF 7.5 Q1 CHEMISTRY, PHYSICAL Applied Surface Science Advances Pub Date : 2024-09-01 DOI:10.1016/j.apsadv.2024.100634
Ruey-Chi Wang, Yi-Hong Zhou, Yu-Hsuan Lee, Hsiu-Cheng Chen, Chi-En Chen
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Abstract

Selected area electrochemical etching (EE) and electrochemical deposition (ED) are widely used for fabricating microstructures and devices, but they require complex processes and expensive equipment and generate significant electrolyte waste. This study demonstrates a novel single-droplet electrochemical system using a triboelectric nanogenerator (TENG) for self-powered selected area EE and ED reactions. Utilizing TENG's pulsed power, Al nanostructures were created by EE, while nano-Ag and Cu2O nanocubes were synthesized by ED. The generated nanomaterials were applied to detect trace chemicals through the Surface-Enhanced Raman Scattering effect. The electrochemical reaction area can be controlled by droplet size, and patterns can be created using a needle movement platform. The size and density of nanostructures can be adjusted by the TENG's current, collision frequency, and electrolyte concentration. The deposition gradient from the center to the edge of the droplet is controlled by the distance between the needle and the substrate. COMSOL Multiphysics calculations show that a smaller D creates a larger electric field gradient. However, the varied deposition gradients were attributed to competition of electric field, diffusion effects, and capillary flow. This proposed green technology offers low cost, simplicity, no waste electrolyte, and self-powering capabilities, pioneering new research directions in EE and ED.

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用于化学传感应用的 TENG 驱动的单液滴绿色电化学蚀刻和沉积
选区电化学蚀刻(EE)和电化学沉积(ED)被广泛用于制造微结构和器件,但它们需要复杂的工艺和昂贵的设备,并且会产生大量电解液废物。本研究展示了一种新型单液滴电化学系统,该系统使用三电纳米发电机(TENG)为选定区域的 EE 和 ED 反应提供自供电。利用 TENG 的脉冲功率,通过 EE 生成了铝纳米结构,而通过 ED 合成了纳米银和 Cu2O 纳米立方体。生成的纳米材料通过表面增强拉曼散射效应用于检测痕量化学物质。电化学反应区域可由液滴大小控制,并可利用针移动平台创建图案。纳米结构的大小和密度可通过 TENG 的电流、碰撞频率和电解液浓度进行调节。从液滴中心到边缘的沉积梯度由针头和基底之间的距离控制。COMSOL Multiphysics 计算表明,D 越小,电场梯度越大。然而,不同的沉积梯度归因于电场竞争、扩散效应和毛细管流动。这项拟议的绿色技术具有成本低、简单、无废电解质和自供电能力等特点,开创了电子工程和教育学的新研究方向。
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来源期刊
CiteScore
8.10
自引率
1.60%
发文量
128
审稿时长
66 days
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