A new four-terminal hybrid silicon/organic field-effect sensor device

63rd Device Research Conference Digest, 2005. DRC '05. Pub Date : 2005-12-12 DOI:10.1109/DRC.2005.1553079

D. Sharma, D. Fine, A. Dodabalapur

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引用次数: 2

Abstract

We present the first demonstration of a novel field-effect device which has two channels: one formed in an organic semiconductor and the second in silicon. The channels are coupled such that one gates the other, with the organic channel exposed to air such that it is able to interact with chemicals in the ambient. This device represents a major improvement over both the traditional CHEMFET (which is a silicon MOSFET with the gate uncovered to be chemically sensitive) (Janata, 1989), and an organic transistor chemical sensor (Crone et al., 2001). While the device we developed can also function as a traditional CHEMFET, one of the more powerful sensing modes occurs when the two channels are coupled and changes in the organic channel carrier density in response to analyte delivery are reflected as changes in the current through the silicon channel. Another unique sensing mode, which appears to be the most sensitive, is designated as the chemical memory mode. In this mode analyte molecules result in trapped charges in the organic semiconductor which change the threshold voltage of the silicon FET. We have observed a response in the chemical memory mode that is between 10 and 100 times more intense than the response in the traditional CHEMFET mode

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一种新型四端硅/有机杂化场效应传感器装置

我们首次展示了一种具有两个通道的新型场效应器件:一个在有机半导体中形成，另一个在硅中形成。这些通道是耦合的，一个通道连接另一个通道，有机通道暴露在空气中，这样它就能与环境中的化学物质相互作用。该器件代表了传统CHEMFET(这是一个硅MOSFET与栅极裸露的化学敏感)(Janata, 1989)和有机晶体管化学传感器(Crone等人，2001)的重大改进。虽然我们开发的器件也可以作为传统的CHEMFET，但当两个通道耦合时，更强大的传感模式之一就会发生，并且有机通道载流子密度的变化响应于分析物的传递，反映为通过硅通道的电流的变化。另一种独特的感知模式，似乎是最敏感的，被指定为化学记忆模式。在这种模式下，分析物分子在有机半导体中产生捕获电荷，从而改变硅场效应管的阈值电压。我们已经观察到化学记忆模式下的响应强度是传统CHEMFET模式下响应强度的10到100倍

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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63rd Device Research Conference Digest, 2005. DRC '05.

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