Flower-Like ZnO Nanorods Synthesized by Microwave-Assisted One-Pot Method for Detecting Reducing Gases: Structural Properties and Sensing Reversibility

• Published in: Frontiers in chemistry Vol. 8; p. 456
• Main Authors: Aljaafari, Abdullah, Ahmed, Faheem, Awada, Chawki, Shaalan, Nagih M
• Format: Journal Article
• Language: English
• Published: Switzerland Frontiers Media S.A 02.07.2020
• Subjects: carbon monoxide; Chemistry; gas sensor; hydrogen; methane; nanoflowers; ZnO nanorods; ZnO nanorods; carbon monoxide; gas sensor; methane; nanoflowers; hydrogen
• ISSN: 2296-2646; 2296-2646
• DOI: 10.3389/fchem.2020.00456

In this work, flower-like ZnO nanorods (NRs) were successfully prepared using microwave-assisted techniques at a low temperature. The synthesized NRs exhibited a smooth surface and good crystal structure phase of ZnO. The sharp peak of the XRD and Raman spectrum confirmed the high crystallinity of these ZnO NRs with a pure wurtzite structure. The nanorods were ~2 μm in length and ~150 nm in diameter, respectively. The electron diffraction pattern confirmed that the single crystal ZnO nanorods aligned along the [001] plane. The NRs were applied to fabricate a gas sensor for reducing gases such as CH , CO, and H . The sensor showed a good performance and sensitivity toward the target gases. However, its response toward CH and CO was higher compared to H gas. Although the operating temperature was varied from room temperature (RT) up to 350°C, the sensor did not show a response toward any of the target gases in the range of RT-150°C, but dramatic enhancement of the sensor response was observed at 200°C, and up to higher temperatures. This behavior was ascribed to the activity of the smooth surface and the reactivity of surface oxygen species with the targeted gases. The sensor response was measured at various gas concentrations, where the calibration curve was shown. The gas sensing mechanism was described in terms of the reaction of the gases with the transformed oxygen species on the surface of the oxides.