Selective discrimination of hazardous gases using one single metal oxide resistive sensor

•Nickel oxide polycrystalline nanowires are grown via hydrothermal way & calcination.•The nanosensor undergoes a thermal gradient, becoming a virtual array.•7 hazardous gases are tested, giving each a different thermal fingerprint.•The nanosensor shows categorization (100%) and quantitative pred...

Full description

Saved in:
Bibliographic Details
Published inSensors and actuators. B, Chemical Vol. 277; pp. 121 - 128
Main Authors Tonezzer, Matteo, Le, Dang Thi Thanh, Iannotta, Salvatore, Van Hieu, Nguyen
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 20.12.2018
Elsevier Science Ltd
Subjects
Ammonia
Capillarity
Fingerprints
Gas detectors
Gas sensors
Hazardous air pollutants
Hazardous gas
Hydrogen sulfide
Liquefied petroleum gas
Machine learning
Metal oxide
Metal oxides
Nanostructured materials
Nanowire
Nanowires
Nickel oxides
Pollutants
Resistive gas sensor
Selectivity
Sensor arrays
Temperature gradients
Metal oxide
Nanowire
Resistive gas sensor
Selectivity
Hazardous gas
Online AccessGet full text

Cover

More Information
Summary:•Nickel oxide polycrystalline nanowires are grown via hydrothermal way & calcination.•The nanosensor undergoes a thermal gradient, becoming a virtual array.•7 hazardous gases are tested, giving each a different thermal fingerprint.•The nanosensor shows categorization (100%) and quantitative prediction (error <15%). Monitoring of hazardous gases is nowadays very important, since the urbanized environment is more subject to this kind of pollutants. Therefore, a capillary network of small gas sensors capable to check the quality of the environment is necessary. Metal oxide gas nanosensors are small economic devices that can be easily integrated in any context, however they unfortunately lack of selectivity. We present an approach using hydrothermally grown nickel oxide nanowires working at different temperatures and creating a virtual sensors array, thus exploiting the thermal fingerprints (sensor response as a function of temperature) of the gases. Using only one nanostructured material (nickel oxide) and different machine learning techniques, the system can easily discriminate any of 7 harmful gases (C2H5OH, H2, CO, LPG, CO2, NH3 and H2S, all of them reducing gases) with an accuracy of 100%. Furthermore, the nanosensor also evaluates the gas concentration with an average error lower than 15%. Our results show that, exploiting thermal fingerprints from a temperature gradient, single metal oxide resistive nanosensors can efficiently discriminate specific hazardous gases.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2018.08.103