Abstract
This paper describes the scalable fabrication of smart electronic textiles (e-textiles) capable of simultaneous sensing, filtration, and detoxification of sulfur dioxide (SO(2)). The templated method converts pre-deposited copper metal into copper hydroxide followed by conversion into a copper-based hexahydroxytriphenylene MOF (Cu(3)(HHTP)(2)) to afford a large area (10 × 10 cm(2)) conductive coating (sheet resistance = 0.1-0.3 MΩ). The resulting e-textiles achieve sensing (theoretical limit of detection (LOD) of 0.43 ppm), filtration (adsorption uptake of 1.9 mmol g(-1) and 0.83 mmol g(-1) for MOF powder and MOF/textile at 1 bar and 298 K), and detoxification (redox conversion of SO(2) gas into solid sulfate) due to the selective material-analyte interactions. This scalable method for generating e-textiles is a promising approach for the fabrication of smart membrane materials with multifunctional performance characteristics.