Ammonia Sensor Based on Co2+/SCN- Modified Core-Shell MCM-41 for Rapid Naked-Eye Colorimetric Detection

Mesoporous silica materials have been widely used as gas adsorbents due to their excellent adsorption ability, large specific surface area, simple preparation process, and convenient functionalization. In this study, a core-shell mesoporous material MCM-41@SiO2 was synthesized and functionalized by CoCl2, and subsequently KSCN, to prepare an ammonia adsorbent. The adsorbent was proved to possess high surface area, good sphericity, uniform size, good dispersibility, and high adsorption capability following DLS, SEM, TEM, and a static adsorption study. Moreover, the successful functionalization and thermal stability were confirmed by FT-IR, XPS, and TGA. The material was then used to fabricate a glass tube sensor for the rapid naked-eye detection of ammonia gas. The sensor showed good performance in terms of sensing speed, selectivity, accuracy, and reusability. Within 5 s, NH3 could be detected by the discoloration, and a wide NH3 concentration from 20 to 1000 ppm could be detected. It also showed a good linear relationship between discoloration length and ammonia concentration. A reversible color change from blue to yellow indicated the presence of NH3, which was attributed to the formation and disassembly of ammonia-containing complex [Co(NH3)(6)(NCS)(2)]. With fast adsorption, naked-eye sensing properties, and good selectivity, the sensor holds good promise for indoor NH3 sensing and other more complicated situations.

Automated summary

In this study, a core-shell mesoporous material MCM-41@SiO2 functionalized with CoCl2 and KSCN was synthesized as an ammonia adsorbent. The material showed high surface area, sphericity, uniform size, dispersibility, and adsorption capability. Furthermore, a glass tube sensor was fabricated using the material for rapid naked-eye detection of ammonia gas, showing good sensing speed, selectivity, accuracy, and reusability. The sensor holds promise for indoor NH3 sensing and other more complicated situations.