AI Article Synopsis
- Recent interest in air pollution sensors using organic transistors is hindered by low responsiveness and slow reaction times due to the properties of organic semiconductors and thick active layers.
- This study explores the use of a porous material, ZIF-8, as an analyte channel for enhancing these sensors, comparing it to various carbonized versions.
- The results showed that the polythiophene/ZIF-8 hybrid films significantly improved the sensor's performance, but the carbonized ZIFs did not enhance detection efficiency due to structural issues.
Article Abstract
Air pollution sensors based on organic transistors have attracted much interest recently; however, the devices suffer from low responsivity and slow response and recovery rates for gas analytes. These shortcomings are attributed to the low charge-carrier mobility of organic semiconductors and to a structural limitation resulting from the use of a thick and continuous active layer. In the present work, we investigated the material properties of a multiscale porous zeolitic imidazolate framework, [Zn(2-methylimidazole)] (ZIF-8), and examined its potential as an analyte channel material inserted at an organic-transistor active layer. A series of carbonized zeolitic imidazolate frameworks (ZIFs) were prepared by thermal conversion of ZIF-8 and also studied for comparison. The microstructures, morphologies, and optical/electrical characteristics of polythiophene/ZIF-8 hybrid films were systematically investigated. Organic-transistor-type nitrogen dioxide sensors based on the polythiophene/ZIF-8 hybrid films showed substantially improved sensing properties, including responsivity, response rate, and recovery rate. The electrical conductivity of the carbonized ZIF-8s enhanced the field-effect mobility of the organic transistors; however, the sensing performance was not improved, because of the closed pore structures resulting from the carbonization. These results provide invaluable information and useful insights into the design of transistor-type gas sensors based on organic semiconductor/metal-organic framework hybrid films.
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| http://dx.doi.org/10.1021/acsami.1c04570 | DOI Listing |
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