Au nanoparticles decorated GaN nanoflowers with enhanced NH3 sensing performance at room temperature

Surface modification with noble metal is considered as an effective strategy to enhance sensing performance of semiconductor gas sensors. In this work, gold nanoparticles (Au NPs) decorated Gallium Nitride nanoflowers (Au-GaN NFs) have been synthesized successfully by a feasible hydrothermal method combined with high temperature nitridation and followed by in-situ reduction process. The characterizations of the structure and morphology of as-obtained Au-GaN NFs indicated that the Au NPs were successfully loaded on the surface of GaN. The excellent gas sensing performance was observed for GaN of 2 mol% Au loaded, including the high response (86.8 %) to 100 ppm NH3 with fast response/recovery time (41 s/169 s) at room temperature, low theoretical limit of detection (72 ppb), good stability and selectivity. Besides, the influence of humidity on the performance of sensors was explored, where the response can be reached 56.5 % towards 100 ppm NH3 under 70 % RH. The improvement of the sensing performance of Au-GaN NFs sensor can be attributed to the combined action of chemical and electronic sensitization of Au NPs. This work provides a candidate of Au-GaN NFs for the development of wireless sensing system in NH3 monitoring.

Automated summary

In this study, gold nanoparticles decorated Gallium Nitride nanoflowers were successfully synthesized by a hydrothermal method combined with high temperature nitridation and in-situ reduction process. The as-obtained Au-GaN NFs showed excellent gas sensing performance, including high response (86.8%) to 100 ppm NH3 with fast response/recovery time (41 s/169 s) at room temperature, low theoretical limit of detection (72 ppb), good stability, and selectivity. The influence of humidity on the sensor performance was also explored. This work provides a candidate material for the development of wireless sensing system in NH3 monitoring.