Abstract
As a new type of one-dimensional nanomaterial, carbon nanotubes (CNTs) have been used as a chemical sensing material due to their excellent electrical, mechanical and chemical properties. Several recent studies have attempted to obtain an electrochemical sensor based on CNTs, and CNT-based humidity sensors have potential applications in industrial, agricultural and medical fields and in smart wearable electronic devices. Although various CNT-based humidity sensors have been reported, in this work, we investigated the humidity effects in depth and the underlying mechanisms according to CNT type, i.e., semiconducting (s-CNT) and metallic (m-CNT) CNTs, which is determined by the chiral vector during CNT growth. For this purpose, we fabricated CNT-based humidity sensors with highly purified, solution-processed 99% single-walled s-CNT and m-CNT network films bridged by palladium (Pd) electrodes. The fabricated sensors exhibited completely different humidity responses, as denoted by the film resistance as a function of the relative humidity (RH), according to the CNT type. In the s-CNT-based sensor, the resistance tended to decrease as the RH increased, while the m-CNT-based sensor showed the opposite tendency. Based on these results, a humidity sensing mechanism according to the CNT type was proposed in this work. We believe that our findings can serve as design guidelines for CNT-based humidity sensors.
Highlights
The ability to monitor humidity in ambient air has become increasingly important recently and is essential in the fields of modern industrial and agricultural production, system control, quality storage, and medical care [1]–[4]
To provide the necessary electrical contacts to measure the change in resistance depending on the relative humidity (RH) levels, an interdigitated electrode structure was introduced in the carbon nanotubes (CNTs)-based humidity sensor
We demonstrated humidity sensors based on different types of CNTs, including semiconducting CNTs (s-CNTs) and metallic CNTs (m-CNTs)
Summary
The ability to monitor humidity in ambient air has become increasingly important recently and is essential in the fields of modern industrial and agricultural production, system control, quality storage, and medical care [1]–[4]. A two-terminal sensor based on two types of solution-processed CNTs (i.e., s- and m-CNTs) have been reported for changes in electrical current to saturated water vapor [26], but detail characterization by humidity responses and their sensing mechanism have not been investigated fully.
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