CdO–ZnO nanorices for enhanced and selective formaldehyde gas sensing applications

This paper reports synthesis, properties and gas sensing applications of ZnO nanoflowers and CdO–ZnO nanorices prepared by hydrothermal process. The morphological characterizations confirmed the formation of well-defined nanoflowers and nanorices structures for ZnO and CdO–ZnO nanomaterials, respect...

Full description

Saved in:
Bibliographic Details
Published in:Environmental research 2021-09, Vol.200, p.111377-111377, Article 111377
Main Authors: Umar, Ahmad, Ibrahim, Ahmed A., Kumar, Rajesh, Algadi, Hassan, Albargi, Hasan, Alsairi, Mabkhoot A., Alhmami, Mohsen A.M., Zeng, Wen, Ahmed, Faheem, Akbar, Sheikh
Format: Article
Language:English
Subjects:
CdO–ZnO
Formaldehyde
Gas sensor
Nanoflowers
Nanorices
ZnO
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This paper reports synthesis, properties and gas sensing applications of ZnO nanoflowers and CdO–ZnO nanorices prepared by hydrothermal process. The morphological characterizations confirmed the formation of well-defined nanoflowers and nanorices structures for ZnO and CdO–ZnO nanomaterials, respectively. The structural properties revealed the wurtzite hexagonal phase of the synthesized materials. The sensor devices based on ZnO nanoflowers and CdO–ZnO nanorices were fabricated and tested towards various gases including ethanol, methanol, ammonia, carbon monoxide, methane and formaldehyde. The fabricated gas sensor based on CdO–ZnO nanorices exhibited a high response (34.5) towards 300 ppm formaldehyde gas at 350 °C compared to ZnO nanoflowers (14.5) under the same experimental conditions. The response and recovery times for ZnO nanoflowers-based sensor were~9.8 s and ~6 s while for CdO–ZnO based sensor, these were ~10s and ~6s, respectively. A rapid response (34.5) for CdO–ZnO nanorices based formaldehyde gas sensor was observed as compared to other gases such as ammonia (12.3), methanol (16.5), ethanol (20), carbon monoxide (16.3) and methane (12.4), which confirm the high-selectivity towards formaldehyde gas. Finally, a plausible formaldehyde gas sensing mechanism is proposed. •ZnO nanoflowers and CdO–ZnO nanorices were hydrothermally synthesized and characterized.•HCHO gas sensor responses of ZnO nanoflowers and CdO–ZnO nanorices based sensors were compared.•CdO–ZnO nanorices based sensor exhibited a high response as compared to ZnO nanoflowers.•Response and recovery times for ZnO nanoflowers and CdO–ZnO based sensors were ~9.8 s, ~6 s and ~10s and ~6s, respectively.
ISSN:0013-9351
1096-0953
DOI:10.1016/j.envres.2021.111377