Preparation of biomolecular anthocyanin-immobilized plasma-cured nonwoven fibers from pomegranate (Punica granatum L.) and recycled cotton waste for detection of ammonia

Abstract

Cotton fibers have been one of the major resources for various modern textile and non-textile industries. They are breathable, soft, and high absorbent natural fibers with a low production cost. Cotton fibers have found uses in a wide range of fields, such as medical field, automobile industry, and furniture design. However, there have been increasing demands to find out other resources for cotton production at high quality and low cost for high technological applications, such as colorimetric sensors. In this work, we provide a novel technique for plasma-induced coloring of nonwoven recycled cotton waste with an anthocyanin natural probe obtained from pomegranate (Punica granatum L.) peel. High-performance liquid chromatography (HPLC) was used to study the anthocyanin extract. Mordant was employed to bind anthocyanin to nonwoven fibers, creating an anthocyanin-mordant coordinative complex. The diameters of the anthocyanin-mordant complex particles were between 5 and 15 nm. A small coating layer of anthocyanin probe was applied to plasma-activated nonwoven cotton. Coloration parameters, absorbance spectra, and colorimetric strength (K/S) data showed that anthocyanin-finished nonwoven cotton had a detection limit of 1–250 ppb of aqueous ammonia, with a corresponding colorimetric change from purple (549 nm) to white (393 nm) due to intramolecular charge transfer. The results demonstrated satisfactory colorfastness of the anthocyanin-dyed nonwoven cotton fibers, UV blocking, and antibacterial efficacy. Promising portable colorimetric technology of anthocyanin-dyed nonwoven cotton fibers was developed for onsite detection of ammonia that can cause severely harmful effects on human organs or even death. Signs of a high surface area in the sensor material include anthocyanin-mordant complex nanoparticles and cotton microfibers.