Abstract
We report a facile method for preparing silver-loaded membranes for point-of-use disinfection and disaster relief applications. A bio-inspired material, polydopamine, was coated onto a highly porous nanofibrous polyacrylonitrile substrate. We then take advantage of the redox properties of polydopamine to form silver nanoparticles in situ. These nanoparticles were uniformly distributed on the surface of nanofibers with no apparent agglomeration at a silver loading up to 4.36 wt.% (cPAN-Ag1.5). The silver-incorporated membrane cPAN-Ag1.5 achieved a high pure water flux of 130 Lm−2 h−1 at 10-cm water head, demonstrating the feasibility of energy-efficient gravity-driven filtration and eliminating the need for electrical power. The strong anti-bacterial activity and high physical rejection of the membrane led to an excellent disinfection power, with no viable bacterial cells detected in its permeate water. The membrane exhibited >7 log reduction for E. coli and >6 log reduction for B. subtilis. The strategy reported here provides an efficient and green route to synthesize point-of-use membranes. Combining their excellent permeability and disinfection effectiveness, these membranes offer an ideal solution to water supply in disaster-affected areas.
Highlights
Natural disasters cause loss of life and severe damages of infrastructures
We investigated a novel bio-inspired method for incorporating silver nanoparticles onto a PDA-coated PAN nanofibrous membrane (Fig. 1)
The results indicated that the viability ratio decreased when coated PAN (cPAN)-Ag1.5 nanofibrous membranes were used compared to the PAN and cPAN membranes, confirming that bacterial cells were removed and killed by cPAN-Ag1.5 due to the combined physical separation and silver disinfection[35]
Summary
Natural disasters cause loss of life and severe damages of infrastructures. Providing safe drinking water in disaster-affected areas plays a critical role to prevent the outbreak of waterborne diseases in the aftermath. Damaged infrastructure and lacking of reliable power supply often render these conventional water treatment technologies not feasible in disaster-affected areas[3]. Some examples of point of use technologies for disaster relieve include thermal based processes, media filtration, MF/UF, and forward osmosis (FO)[4,5,6,7] Many of these methods suffer from their relatively low productivity (e.g., thermal processes and FO) or limited treatment efficiency (e.g., media filtration). Silver-based disinfection has been increasingly used as a novel point-of-use technology for disaster relief because of their powerful biocidal ability[8, 9]. The strategy reported in this study provides a new dimension of designing high-efficiency and high-reliability point-of-use water treatment for disaster relief
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