Tin oxide (SnO 2 )-based thin films were deposited on alumina printed circuit boards via electron beam evapo ration to fabricate CO 2 gas sensors operating at room temperature. Femtosecond laser surface nanotexturing was applied as a novel approach to optimize key gas sensitivity parameters, including surface roughness and grain size. Raman and X-ray photoelectron spectroscopy revealed that the sensitive layer consists of a 1 μm SnO film with a non-stoichiometric SnO 2 upper layer for the as-deposited film. The electronic disparity between these layers forms a native SnO-SnO 2 interface, creating a p-n junction that enhances sensor sensitivity. This sensor shows a sensing response ranging from 7 % to 20 % for CO 2 concentrations of 1000 to 2000 ppm, and up to 40 % at 5000 ppm. Laser irradiation introduced periodic surface structures (~ 800 nm), increasing the roughness and the number of active sites for the gas sensing. Although no significant improvements were observed in terms of sensitivity, the fs-laser treated sensor exhibited enhanced stability and reproducibility, indicating its potential for low-energy consumption gas sensing platforms for indoor air quality applications.
Engineered SnO2-based thin films for efficient CO2 gas sensing at room temperature
Bolli E.
;Bellucci A.;Mastellone M.;Mezzi A.;Orlando S.;Salerno R.;Santagata A.;Valentini V.;Trucchi D. M.
2025
Abstract
Tin oxide (SnO 2 )-based thin films were deposited on alumina printed circuit boards via electron beam evapo ration to fabricate CO 2 gas sensors operating at room temperature. Femtosecond laser surface nanotexturing was applied as a novel approach to optimize key gas sensitivity parameters, including surface roughness and grain size. Raman and X-ray photoelectron spectroscopy revealed that the sensitive layer consists of a 1 μm SnO film with a non-stoichiometric SnO 2 upper layer for the as-deposited film. The electronic disparity between these layers forms a native SnO-SnO 2 interface, creating a p-n junction that enhances sensor sensitivity. This sensor shows a sensing response ranging from 7 % to 20 % for CO 2 concentrations of 1000 to 2000 ppm, and up to 40 % at 5000 ppm. Laser irradiation introduced periodic surface structures (~ 800 nm), increasing the roughness and the number of active sites for the gas sensing. Although no significant improvements were observed in terms of sensitivity, the fs-laser treated sensor exhibited enhanced stability and reproducibility, indicating its potential for low-energy consumption gas sensing platforms for indoor air quality applications.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
