Design of flower-like V2O5 hierarchical nanostructures by hydrothermal strategy for the selective and sensitive detection of xylene

Abstract

Present work proposes the insight towards synthesis of flower-like vanadium oxide hierarchical nanostructures (V2O5 HNs) through a simple and template-free hydrothermal method and their utilization as a potential xylene gas sensing materials. XRD and XPS analysis supports to the configuration of highly crystalline orthorhombic phase of V2O5. Surface morphologies of V2O5 were controlled through varying the reaction times during hydrothermal synthesis. SEM and TEM studies undoubtedly corroborates that the flower-like V2O5 HNs (3–5 μm in diameters) are composed of large number of nanosheet- and nanoneedle-type structures. BET and BJH analysis supports to the mesoporous character of V2O5 HNs with specific surface area of 19.5291 m2/g. Gas sensing studies on as-fabricated V2O5 HNs sensors were performed towards a various target gases, temperatures, and varying concentrations thoroughly and described. Gas sensing studies demonstrate that the flower-like V2O5 HNs sensors are selective and effective towards xylene @300 °C. Among various V2O5 HNs sensors, the sensor based on V2O5-3 exhibits maximum response of 3.03 to 500 ppm xylene together with good response repeatability and long term stability (towards 100 ppm, Ra/Rg = 2.20) @300 °C. Finally, the selective detection of xylene using as-grown flower-like V2O5 HNs can cover the road in the direction of the development of sensing systems for the acute detection and monitoring of toxic xylene.