Nitrogen dioxide sensing based on multiple-morphology cuprous oxide mixed structures anchored on reduced graphene oxide nanosheets at room temperature.

Sensitive detection of trace nitrogen dioxide (NO) gas at room temperature is of urgent necessity in the fields of healthcare and environment monitoring. To achieve this goal, we report on a porous composite film featuring reduced graphene oxide (rGO) nanosheets as the template platform of nanostructured cuprous oxide (CuO) nanowires and nanoparticles via a hydrothermal method. The sensor performance was investigated in terms of sensing response, optimal operation temperature, repeatability, long-term stability, selectivity and humidity effect on NO sensing. The sensor response achieved 0.66 towards 50 ppb NO gas with a full recovery at room temperature (25 °C ± 2 °C), which was among the best cases of CuO-related NO detection concerning sensor response and operation temperature. Moreover, a modest repeatability, stability, selectivity as well as a negligible humidity effect on NO sensing were exhibited. A mass of interspaces existing within nanostructured composites as well as the synergistic effect between rGO and CuO materials endowed the sensing layer with favorable gas accessibility and sufficient gas-solid interaction. Simultaneously, highly conductive rGO nanosheets facilitated an effective electron transfer and collection. In brief, the as-prepared rGO/CuO sensors showed a competitive room temperature detection capability for ppb-level NO gas, providing a vast potential in the future applications such as the real-time monitoring of ultralow emission.