Abstract
Oxide semiconductor In2O3 has been extensively used as a gas sensing material for the detection of various toxic gases. However, the pure In2O3 sensor is always suffering from its low sensitivity. In the present study, a dramatic enhancement of sensing characteristic of cubic In2O3 was achieved by deliberately fabricating p-n heterojunction-like NiO/In2O3 composite microparticles as sensor material. The NiO-decorated In2O3 p-n heterojunction-like sensors were prepared through the hydrothermal transformation method. The as-synthesized products were characterized using SEM-EDS, XRD, and FT-IR, and their gas sensing characteristics were investigated by detecting the gas response. The experimental results showed that the response of the NiO/In2O3 sensors to 600 ppm methanal was 85.5 at 260°C, revealing a dramatic enhancement over the pure In2O3 cubes (21.1 at 260°C). Further, a selective detection of methanol with inappreciable cross-response to other gases, like formaldehyde, benzene, methylbenzene, trichloromethane, ethanol, and ammonia, was achieved. The cause for the enhanced gas response was discussed in detailed. In view of the facile method of fabrication of such composite sensors and the superior gas response performance of samples, the cubic p-n heterojunction-like NiO/In2O3 sensors present to be a promising and viable strategy for the detection of indoor air pollution.
Highlights
Indoor air pollution has been realized by many people with respect to public health
In the same 600 ppm measurement methanal was system, the response 28.5 at 280∘C, which of pure In2O3 to was much lower than that of the p-n heterojunction-like NiO/In2O3. These findings showed that the p-n heterojunction-like gas sensor had achieved more superior sensing properties than that of bare In2O3 materials
The experimental results of detecting the gas response verified that the gas sensing characteristic of NiO/In2O3 sensors was significantly different from the pure In2O3 cubes
Summary
Indoor air pollution has been realized by many people with respect to public health. The most commonly used technologies for detecting the low concentration methanal in air include fluorimetry [2], colorimetry [3], high-performance liquid chromatography (HPLC) [4], gas chromatography (GC) [5], and infrared detection [6] In contrast to such traditionally available approaches for detecting methanal, another alternative monitor using oxide semiconductor as sensor has been recently applied due to its various superiorities, such as low cost, good stability, and short response time [7,8,9,10]. In view of the facile method of fabrication of the composite sensors and the superior gas response performance, we believed that the pn heterojunction-like NiO/In2O3 sensors present to be a promising and viable strategy for the detection of indoor methanal pollution
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