Copper 2-Methylimidazole Nanostructure-Based Colorimetric Fabric Sensor for Real-Time Monitoring of Ambient Sulfur Oxides

For effective protection from exposure to hazardous gases, a facile strategy of real-time gas monitoring is highly needed. In this study, a novel colorimetric indicator that allows the visual detection of ambient sulfur oxides (SOx) is developed, applying copper 2-methylimidazole [Cu(mIm)] nanocrystals to a cellulose fabric. By optimization of the molar ratio of copper to mIm, the properties of the treated fabric are improved for the Cu(mIm) loading capacity, gas adsorption performance, and colorimetric response. It is revealed that the role of environmental humidity is crucial for effective adsorption and chromatic reaction of Cu(mIm) because the hydrated Cu(mIm) surface facilitates SO2 adsorption, producing reactive species of HSO3- or SO42-. Those reactive SOx species cause the structural transformation of Cu(mIm) and ultimately lead to a chromatic response. The chromatic reaction takes place close to the breakthrough concentration of 5 ppm, demonstrating that the Cu(mIm) fabric can be applied as a practical service-life indicator, timely signaling the replacement time of protective materials. It is anticipated that the proposed strategy offers an effective SOx monitoring solution for application in various fields that call for facile gas detection.

Automated summary

This study develops a novel colorimetric indicator for real-time visual detection of ambient sulfur oxides (SOx). By optimizing the ratio of copper to mIm, the treated fabric shows improved Cu(mIm) loading capacity, gas adsorption performance, and colorimetric response. It is found that environmental humidity plays a crucial role in the adsorption and chromatic reaction of Cu(mIm). The chromatic reaction occurs close to the breakthrough concentration of 5 ppm, enabling timely replacement of protective materials.