Selective Detection of CO Using Proton-Conducting Graphene Oxide Membranes with Pt-Doped SnO₂ Electrocatalysts: Mechanistic Study by Operando DRIFTS

Abstract: To reduce the risk of carbon monoxide (CO) poisoning, there is a strong need for small, compact gas sensors to detect and monitor CO at ppm concentrations. In this study, we focused on detecting CO with electrochemical sensors based on proton-conducting graphene oxide (GO) nanosheets at room temperature. We found that a Ce-doped GO nanosheet membrane fitted with the sensing electrode composed of Pt (10 wt %)-doped SnO 2 nanocrystals exhibits an excellent sensor response to CO at 25 °C. Pt doping of SnO 2 nanoc… Show more

“…On the other hand, graphene oxide (GO) is a nanomaterial derived from graphene, which contains a large number of active sites owing to the presence on its surface of oxygen-containing functions, such as hydroxyl, epoxy, and carbonyl groups. These oxygenated functionalities are responsible for the higher reactivity of GO. , Several research studies have been dedicated to the application of GO and heteroatom-doped GO in the field of gas sensors. Prezioso and co-workers developed a NO 2 sensor based on the GO film and showed that the sensor became inactive when operating temperatures exceeded 200 °C due to the poor thermal stability of GO.…”

“…These oxygenated functionalities are responsible for the higher reactivity of GO. 23 , 24 Several research studies have been dedicated to the application of GO and heteroatom-doped GO in the field of gas sensors. Prezioso and co-workers 23 developed a NO 2 sensor based on the GO film and showed that the sensor became inactive when operating temperatures exceeded 200 °C due to the poor thermal stability of GO.…”

Selective NO₂ Gas Sensors Employing Nitrogen- and Boron-Doped and Codoped Reduced Graphene Oxide

“…On the other hand, graphene oxide (GO) is a nanomaterial derived from graphene, which contains a large number of active sites owing to the presence on its surface of oxygen-containing functions, such as hydroxyl, epoxy, and carbonyl groups. These oxygenated functionalities are responsible for the higher reactivity of GO. , Several research studies have been dedicated to the application of GO and heteroatom-doped GO in the field of gas sensors. Prezioso and co-workers developed a NO 2 sensor based on the GO film and showed that the sensor became inactive when operating temperatures exceeded 200 °C due to the poor thermal stability of GO.…”

“…These oxygenated functionalities are responsible for the higher reactivity of GO. 23 , 24 Several research studies have been dedicated to the application of GO and heteroatom-doped GO in the field of gas sensors. Prezioso and co-workers 23 developed a NO 2 sensor based on the GO film and showed that the sensor became inactive when operating temperatures exceeded 200 °C due to the poor thermal stability of GO.…”

Selective NO₂ Gas Sensors Employing Nitrogen- and Boron-Doped and Codoped Reduced Graphene Oxide

Superselective Hydrogen Separation through a Mixed Conducting Graphene Oxide Membrane