MXene/WO<sub>3</sub> Sensor Array with Improved SNN Algorithm for Accurate Identification of Toxic Gases
Liangchao Guo, Junke Wang, Haoran Han, Peng Wang, Yunxiang Lu, Qilong Yuan, Chunyu Du, Shuo Yin, Ye Zhou, Chao Zhang
Abstract
Gas sensing is pivotal in critical areas such as industrial production and food safety. This study explores the gas classification capabilities of MXene-based gas sensors. Pure V 2 CT x MXene and an MXene/WO 3 nanocomposite were synthesized, and MXene-based gas sensors were integrated into a 2 × 2 rudimentary electronic nose array. The tests on gas sensitivity revealed that the inclusion of WO 3 nanoparticles (NPs) boosted the sensor’s response to 10 ppm of NO 2 from 2.82 to 3.45 at room temperature. Moreover, the sensor showcased a rapid response/recovery duration of 74.5/149.0 s, excellent environmental stability, and long-term reliable sensing performance. Furthermore, we have improved the method of accurately identifying four toxic gases detected by an MXene-based sensor array using a spiking neural network (SNN) based on the memristive system. Also, the performance of this identification method revealed that the method achieved 95.83% accuracy in the identification of the four gases. Notably, the improved SNN demonstrated approximately 5% higher accuracy than the other gas recognition algorithm. These results highlight the potential of SNN as a powerful tool to accurately and reliably identify toxic gases based on the gas sensor array.