Synthesis of Porous Hierarchical In2O3 Nanostructures with High Methane Sensing Property at Low Working Temperature

Different hierarchical porous In2O3 nanostructures were synthesized by regulating the hydrothermal time and combining it with a self-pore-forming method. The gas-sensing test results show that the response of the sensor based on In2O3 obtained after hydrothermal reaction for 48 h is about 10.4 to 500 ppm methane. Meanwhile, it possesses good reproducibility, stability, selectivity and moisture resistance as well as a good exponential linear relationship between the response to methane and its concentration. In particular, the sensor based on In2O3 can detect a wide range of methane (10 similar to 2000 ppm) at near-room temperature (30 degrees C). The excellent methane sensitivity of the In2O3 sensor is mainly due to its unique nanostructure, which has the advantages of both porous and hierarchical structures. Combined with the DFT calculation, it is considered that the sensitive mechanism is mainly controlled by the surface adsorbed oxygen model. This work provides a feasible strategy for enhancing the gas sensitivity of In2O3 toward methane at low temperatures.

Automated summary

Different hierarchical porous In2O3 nanostructures were synthesized, and their gas sensing properties towards methane were studied. The results showed that the sensor based on In2O3 obtained after 48-hour hydrothermal reaction had a response of about 10.4 to 500 ppm methane, exhibiting good reproducibility and exponential linear relationship. This study provides a feasible strategy for enhancing the gas sensitivity of In2O3 towards methane at low temperatures.