Controllable construction of ZnSnO3 polyhedrons abundant in oxygen vacancies via cobalt doping and their acetone sensing performance

Increasing attentions have been paid to the development of ZnSnO3-based gas sensors for acetone detection, owing to their unique advantages of high electron mobility, low visible adsorption and excellent electrical conductivity. However, some intrinsic problems associated with low response remain to be satisfactorily resolved. Herein, cobalt (Co) doping was implemented in this work to simultaneously modulate the electronic structure and oxygen vacancy of ZnSnO3, a series of ZnSnO3 doped with varying quantities of Co ions were harvested through a hydrothermal method. The results reveal that the sensor, fabricated using ZnSnO3 with the incorporation of 10 mol% Co ions, manifests exceptional response (109) to 100 ppm acetone at 260 degrees C, accompanied by a speedy response/recover time (21/11 s). Furthermore, the gas device exhibits excellent comprehensive properties, including an ultra-low theoretical limit of detection (25 ppb), reliable long-term stability, as well as good anti-humidity performance. It is concluded by a series of characterization techniques that large BET surface area and abundant oxygen vacancies conduce to the significant enhancement in sensing performance. This study sheds light on fundamental understanding of how to tailor high-performance ZnSnO3based sensing devices for toxic gas detection.