A Comprehensive Modelling Approach for Bio-EDLC systems

2020 IEEE Sensors Pub Date : 2020-10-25 DOI:10.1109/SENSORS47125.2020.9278742

R. Massey, R. Amache, Siziwe Bebe, R. Prakash

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引用次数: 2

Abstract

The impetus to power wearable or miniaturized sensors has led to interest in the Double Layer Capacitor (DLC), a small footprint (ecologically and physically) energy storage device with the optimal benefits of high energy and power density. DLCs leverage complex double layer capacitances dictated by material and electrolyte-interface properties. Moreover, DLC operation is analogous to the sensing mechanism of our reported Organic Electrolyte Gated Field Effect Transistor (OEGFET) biosensor. In this work, we present a comprehensive modelling approach for Bio-electrolyte DLCs (Bio-EDLC) to accurately simulate them as electronic circuit components. This model can further be extended to predict the transient characteristics of our OEGFET Biosensors. We evaluate three common DLC equivalent models — the Classical Equivalent model, Zubieta model and Two-Branch model — to determine which most accurately captures the charge storage characteristics of our novel planar Bio-EDLC, containing a Carrageenan:PVA:Agarose (16:8:1) polymer-blended bioelectrolyte. We establish that Zubieta model most effectively captures the complex internal electrochemistry of these systems, predicting the transient characteristics with a 0.7% standard error (Classical Equivalent: 5.0%; Two-Branch: 1.7%).

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生物edlc系统的综合建模方法

对可穿戴或小型化传感器的动力推动了对双层电容器(DLC)的兴趣，这是一种占地面积小(生态和物理)的能量存储设备，具有高能量和功率密度的最佳优势。dlc利用由材料和电解质界面特性决定的复杂双层电容。此外，DLC操作类似于我们报道的有机电解质门控场效应晶体管(OEGFET)生物传感器的传感机制。在这项工作中，我们提出了一种全面的生物电解质dlc (Bio-EDLC)建模方法，以准确地模拟它们作为电子电路元件。该模型可以进一步扩展到预测我们的OEGFET生物传感器的瞬态特性。我们评估了三种常见的DLC等效模型——经典等效模型、Zubieta模型和双分支模型——以确定哪种模型最准确地捕捉了我们的新型平面Bio-EDLC的电荷存储特性，该模型包含卡拉胶:PVA:琼脂糖(16:8:1)聚合物混合生物电解质。我们建立了Zubieta模型最有效地捕捉了这些系统复杂的内部电化学，预测瞬态特性的标准误差为0.7%(经典等效:5.0%;两个分校:1.7%)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 IEEE Sensors

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