Vapor sensing properties of a conductive polymer composite containing Nickel particles with nano-scale surface features

2013 13th IEEE International Conference on Nanotechnology (IEEE-NANO 2013) Pub Date : 2013-08-01 DOI:10.1109/NANO.2013.6720830

Sarah J. Dempsey, A. Webb, A. Graham, D. Bloor, D. Atkinson, M. Szablewski

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引用次数: 1

Abstract

This paper presents an unusual conductive polymer composite, produced by Peratech Ltd under the trademark QTC™, which has many vapor sensing applications. Nickel particles are intimately coated by an elastomeric binder such that no percolative conduction can occur. However, the nickel particles are shown to possess spiky nanoscale surface features, which promote conduction by a field-assisted quantum tunneling mechanism. Granular QTC™ can be dispersed into a polymer matrix to produce a vapor sensor. Under exposure to vapor, the polymer swells and the resistance of the composite increases. In this work, granular sensors are subjected to acetone and tetrahydrofuran (THF) vapors. The response for THF shows an increase in resistance of a factor of 108, over a time-scale of a few seconds. This response is larger and faster than many conventional vapor sensing composites. This is a significantly larger response than that obtained historically for the same sensor, suggesting that some degree of sensor aging is desirable. The response and subsequent recovery can be explained by a case II diffusion model, and linked to Hildebrand solubility parameters of the vapor and polymer components.

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具有纳米级表面特征的含镍导电聚合物复合材料的气敏性能

本文介绍了一种不同寻常的导电聚合物复合材料，由Peratech Ltd以QTC™商标生产，具有许多蒸汽传感应用。镍颗粒被一种弹性粘合剂紧密地包覆，这样就不会发生渗透传导。然而，镍粒子被证明具有尖锐的纳米级表面特征，这促进了场辅助量子隧道机制的传导。颗粒状QTC™可以分散到聚合物基质中，以产生蒸汽传感器。暴露于蒸汽下，聚合物膨胀，复合材料的电阻增加。在这项工作中，颗粒传感器受到丙酮和四氢呋喃(THF)蒸气的影响。对THF的反应表明，在几秒钟的时间尺度内，电阻增加了108倍。这种响应比许多传统的蒸汽传感复合材料更大、更快。这是一个明显大于历史上获得的相同传感器的响应，这表明某种程度的传感器老化是可取的。响应和随后的恢复可以用案例II扩散模型来解释，并与蒸汽和聚合物组分的希尔德布兰德溶解度参数相关联。

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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2013 13th IEEE International Conference on Nanotechnology (IEEE-NANO 2013)

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