Issue 18, 2018

An ammonia detecting mechanism for organic transistors as revealed by their recovery processes

Abstract

Organic thin film transistor (OTFT) based gas sensors have demonstrated promising applications, owing to their advantages of high selectivity and room temperature operation, accompanied by their low cost, large scale manufacture, and flexibility. However, the understanding of the sensing mechanism is far from clear. Herein, we reveal the sensing mechanism of an organic transistor sensor for ammonia (NH3) detection through studying the recovery behavior in various atmospheres. Inspired by the significant difference in the recovery of the transistor sensor in N2 and in air, we deduced that the operation mechanism should not only involve the NH3–film interaction. Among a series of recovery processes, only upon exposure to wet air can the sensors completely recover in a certain time. Such a phenomenon, coupled with the transistor’s performance evolution under vacuum, directly evidenced the existence of a pre-doping effect in the transistor by water (H2O) in ambient air. As a result, the response to the NH3 analyte is actually a de-doping process via reaction with the H2O. The full recovery in wet air is attributable to re-doping by H2O. Density functional theory (DFT) calculations were employed to assist the understanding of such a sensing mechanism. This study could help in the understanding of the sensing processes in many organic semiconductor based sensors.

Graphical abstract: An ammonia detecting mechanism for organic transistors as revealed by their recovery processes

Supplementary files

Article information

Article type
Paper
Submitted
12 2 2018
Accepted
19 4 2018
First published
20 4 2018

Nanoscale, 2018,10, 8832-8839

An ammonia detecting mechanism for organic transistors as revealed by their recovery processes

X. Zhou, K. Niu, Z. Wang, L. Huang and L. Chi, Nanoscale, 2018, 10, 8832 DOI: 10.1039/C8NR01275J

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