In Situ and 2D and 3D in Silico Redox Cycling Studies for Design Optimization of Coplanar Arrays of Microband Electrodes in a 70 µm × 100 µm Electroactive Footprint

Journal of The Electrochemical Society Pub Date : 2024-06-04 DOI:10.1149/1945-7111/ad5409

Miguel Angel Abrego Tello, Mahsa Lotfi Marchoubeh, Ingrid Fritsch

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Abstract

Optimization of redox-cycling currents was performed by adjusting the height (sidewalls, h), width (w) ,and length (l) of band electrodes and their spacing (wgap) in coplanar arrays restricted to a small-electroactive window of 70 × 100 µm. These arrays can function in µL-volumes for chemical analysis (e.g., in vivo dopamine detection using probes). Experiments were conducted with an array of five electrodes (NE = 5), w = 4.3 µm, wgap = 3.7 µm, h = 0.150 µm, and l = 99.2 µm. Reasons for disparities between currents from experiments and approximate equations were determined by high-density mesh simulations and were found to arise from sluggish heterogeneous electron transfer kinetics and diffusion at electrode ends, edges, and heights. Ferricyanide, with its moderately slow kinetics, exhibits redox-cycling currents that fall below predictions by the equations as wgap decreases and diffusional flux outpaces reaction rates. Simulations aid investigations of various array designs, achievable through conventional photolithography, by decreasing w and wgap and increasing NE to fit within the electroactive window. A coplanar array, NE = 58, w = wgap = 0.6 µm, h = 0.150 µm and l = 100 µm, yielded ferricyanide sensitivities of 0.266, 0.259 nA·µM−1, enhancements of 8× and 9× over w = wgap = 4 µm, and projected dopamine limits of quantification of 139 nM, 171 nM at generator and collector electrodes, respectively

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进行原位、二维和三维硅学氧化还原循环研究，优化 70 微米 × 100 微米电活性基底中的共面微带电极阵列设计

通过调整共面阵列中带状电极的高度（侧壁，h）、宽度（w）和长度（l）及其间距（wgap），对氧化还原循环电流进行了优化。这些阵列可以在微升体积内进行化学分析（例如使用探针进行体内多巴胺检测）。实验中使用了由五个电极组成的阵列（NE = 5），w = 4.3 µm，wgap = 3.7 µm，h = 0.150 µm，l = 99.2 µm。通过高密度网格模拟确定了实验电流与近似方程之间存在差异的原因，发现是由于电极末端、边缘和高度处的异质电子转移动力学和扩散缓慢造成的。随着 wgap 的减小和扩散通量超过反应速率，铁氰化钾的氧化还原循环电流低于方程的预测值。模拟有助于研究各种阵列设计，通过减小 w 和 wgap 以及增加 NE 以适应电活性窗口，可以通过传统的光刻技术实现。一个共面阵列（NE = 58、w = wgap = 0.6 µm、h = 0.150 µm、l = 100 µm）的三氯化铁灵敏度分别为 0.266、0.259 nA-µM-1，比 w = wgap = 4 µm 的灵敏度分别提高了 8 倍和 9 倍，在发生电极和收集电极的多巴胺预计定量限分别为 139 nM 和 171 nM。

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Journal of The Electrochemical Society

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