Lorena Di Zazzo, Ilaria di Filippo, Lorenzo Guido, Gabriele Magna, Larisa Lvova, Fabrizio Caroleo, Manuela Stefanelli, Leonardo Duranti, Sara Nardis, Corrado Di Natale, Roberto Paolesse
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引用次数: 0
摘要
科罗莱是一种收缩卟啉类化合物,具有广泛的化学相互作用,可直接进行合成制备和功能化,并可进行多功能薄膜沉积。这些特性使它们成为化学传感器的理想候选材料。然而,由于珊瑚虫固体薄膜本身的导电性有限,限制了它们在质量和光学传感器中的应用。尽管存在这一障碍,但人们仍对如何将珊瑚虫的敏感特性与易于微型化和集成到低成本电子电路中的特性相匹配产生了浓厚的兴趣。这项研究探索了将[5,10,15-(4-氨基苯基)珊瑚酸铜]导电聚合物薄膜直接简单地沉积到相互咬合电极上的可能性。值得注意的是,电聚合协议允许选择这些薄膜的半导体性质(p 型或 n 型),从而产生两种不同类型的传感器:前者对一氧化氮(NO)具有高灵敏度和选择性,受相对湿度的影响较小;而后者则具有广泛的灵敏度范围。这一突破为开发微型电导气体探测器、非线性电导传感元件和基于聚碳酸酯的电子鼻平台奠定了基础。
Corrole Polymers as a Novel Materials for Room Temperature Resistive Gas Sensors
Corroles, a family of contracted porphyrinoids, exhibit broad chemical interactions, undergo straightforward synthetic preparation and functionalization, and enable versatile thin film deposition. These attributes render them promising candidates for use in chemical sensors. Nevertheless, the inherently limited conductivity of corrole solid films constrains their application in mass and optical sensors. Despite this impediment, there is a great interest in matching the sensitive properties of the corrole with the features of facile miniaturization and integration into low-cost electronic circuits. This work explores the possibility of directly and simply depositing conductometric polymeric films of [5,10,15-(4-aminophenyl)corrolato] copper onto interdigitated electrodes. Remarkably, the electropolymerization protocol allows the selection of the semiconductive nature (p- or n-type) of these films, yielding two distinct sensor types: the former exhibiting high sensitivity and selectivity toward nitrogen monoxide (NO) with a slight influence of relative humidity and the other manifesting a broad spectrum of sensitivities. This breakthrough lays the foundation for developing miniaturized conductometric gas detectors, nonlinear conductometric sensing elements, and electronic nose platforms based on polycorroles.