跨导
材料科学
晶体管
电极
平面的
光电子学
频道(广播)
纳米技术
电气工程
电压
计算机科学
电信
化学
计算机图形学(图像)
工程类
物理化学
作者
Yuanying Liang,Fabian Brings,Vanessa Maybeck,Sven Ingebrandt,Bernhard Wolfrum,Andrij Pich,Andreas Offenhäusser,Dirk Mayer
标识
DOI:10.1002/adfm.201902085
摘要
Abstract Organic electrochemical transistors (OECTs) have emerged as versatile electrophysiological sensors due to their high transconductance, biocompatibility, and transparent channel material. High maximum transconductances are demonstrated facilitating the extracellular recording of signals from electrogenic cells. However, this requires large channel dimensions and thick polymer films. These large channel dimensions lead to low transistor densities. Here, interdigitated OECTs (iOECTs) are introduced, which feature high transconductances at small device areas. A superior device performance is achieved by systematically optimizing the electrode layout regarding channel length, number of electrode fingers and electrode width. Interestingly, the maximum transconductance ( g max ) does not straightforwardly scale with the channel width‐to‐length ratio, which is different from planar OECTs. This deviation is caused by the dominating influence of the source–drain series resistance R sd for short channel devices. Of note, there is a critical channel length (15 µm) above which the channel resistance R ch becomes dominant and the device characteristics converge toward those of planar OECTs. Design rules for engineering the performance of iOECTs are proposed and tested by recording action potentials of cardiomyocyte‐like HL‐1 cells with high signal‐to‐noise ratios. These results demonstrate that interdigitated OECTs meet two requirements of bioelectronic applications, namely, high device performance and small channel dimensions.
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