A route to detect H2 in ambient conditions using a sensor based on reduced Graphene Oxide
In this study, we have fabricated a H2 (g) sensor based on the precise positioning of GO flakes across sputtered aluminium-doped ZnO (AZO) electrodes on a glass substrate using a positive dielectrophoretic force (DEP). GO flakes assembly was performed between AZO electrodes gap of 4 μm and optimized by controlling the DEP parameters. A chemical reduction using a solution of 10 mM sodium borohydride was used to enhance the conductivity of the GO flakes up to two orders of magnitude. The arrangement of the GO flakes, the efficiency of the reduction process, the morphology and the surface potential of these was analyzed by Atomic Force and Kelvin Probe Microscopies. A reduced Graphene Oxide (rGO) work function in the range of 4.7-4.9 eV was obtained. Moreover, the H2 (g) response of rGO/AZO sensor was studied by two types of tests. First test consists of a single 10 min exposure of pure H2 (g), collecting the IV directly data in order to obtain the sensitivity of the rGO to be of ∼100 % at 1 V. Second test consists of a batch of different time exposures to analyze the stress performance and the saturation level of the sensor. Finally, the impact of the ambient conditions on our sensor sensitivity was studied.Graphical abstractChange in resistance of rGO/AZO and AZO sensor under an accumulated exposition at 40 sccm of H2 (g) over time.
Source: Sensors and Actuators A: Physical - Category: Physics Source Type: research
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