Thin-film composite (TFC) membranes still suffer from fouling and biofouling. In this work, by incorporating a graphene oxide (GO)−silver-based metal−organic framework (Ag-MOF) into the TFC selective layer, we synthesized a thin-film nanocomposite (TFN) membrane that has notably improved anti-biofouling and antifouling properties. The TFN membrane has a more negative surface charge, higher hydrophilicity, and higher water permeability compared with the TFC membrane. Fluorescence imaging revealed that the GO−Ag-MOF TFN membrane kills Escherichia (E.) coli more than the Ag-MOF TFN, GO TFN, and pristine TFC membranes by 16, 30, and 92%, respectively. Forward osmosis experiments with E. coli and sodium alginate suspensions showed that the GO−Ag-MOF TFN membrane by far has the lowest water flux reduction among the four membranes, proving the exceptional anti-biofouling and antifouling properties of the GO−Ag-MOF TFN membrane.
This work shows that incorporating highly compatible polyrhodanine nanoparticles (PRh-NPs) into a polyamide (PA) active layer allows for fabricating forward osmosis (FO) thin-film composite (TFC)-PRh membranes that have simultaneously improved antimicrobial, antifouling, and transport properties. To the best of our knowledge, this is the first reported study of its kind to this date. The presence of the PRh-NPs on the surface of the TFC-PRh membranes active layers is evaluated using FT-IR spectroscopy, SEM, and XPS. The microscopic interactions and their impact on the compatibility of the PRh-NPs with the PA chains were studied using molecular dynamics simulations. When tested in forward osmosis, the TFC-PRh-0.01 membrane (with 0.01 wt % PRh) shows significantly improved permeability and selectivity because of the small size and the high compatibility of the PRh-NPs with PA chains. For example, the TFC-PRh-0.01 membrane exhibits a FO water flux of 41 l/(m·h), higher than a water flux of 34 l/(m·h) for the pristine TFC membrane, when 1.5 molar NaCl was used as draw solution in the active-layer feed-solution mode. Moreover, the reverse solute flux of the TFC-PRh-0.01 membrane decreases to about 115 mmol/(m·h) representing a 52% improvement in the reverse solute flux of this membrane in comparison to the pristine TFC membrane. The surfaces of the TFC-PRh membranes were found to be smoother and more hydrophilic than those of the pristine TFC membrane, providing improved antifouling properties confirmed by a flux decline of about 38% for the TFC-PRh-0.01 membranes against a flux decline of about 50% for the pristine TFC membrane when evaluated with a sodium alginate solution. The antimicrobial traits of the TFC-PRh-0.01 membrane evaluated using colony-forming units and fluorescence imaging indicate that the PRh-NPs hinder cell deposition on the TFC-PRh-0.01 membrane surface effectively, limiting biofilm formation.
In
this study, a polyamide forward osmosis membrane was functionalized
with zwitterions followed by the in situ growth of metal–organic
frameworks with silver as a metal core (Ag-MOFs) to improve its antibacterial
and antifouling activity. First, 3-bromopropionic acid was grafted
onto the membrane surface after its activation with
N
,
N
-diethylethylenediamine. Then, the in situ growth
of Ag-MOFs was achieved by a simple membrane immersion sequentially
in a silver nitrate solution and in a ligand solution (2-methylimidazole),
exploiting the underlying zwitterions as binding sites for the metal.
The successful membrane functionalization and the enhanced surface
wettability were verified through an array of characterization techniques.
When evaluated in forward osmosis tests, the modified membranes exhibited
high performance and improved permeability compared to pristine membranes.
Static antibacterial experiments, evaluated by confocal microscopy
and colony-forming unit plate count, resulted in a 77% increase in
the bacterial inhibition rate due to the activity of the Ag-MOFs.
Microscopy micrographs of the
Escherichia coli
bacteria suggested the deterioration of the biological cells. The
antifouling properties of the functionalized membranes translated
into a significantly lower flux decline in forward osmosis filtrations.
These modified surfaces displayed negligible depletion of silver ions
over 30 days, confirming the stable immobilization of Ag-MOFs on their
surface.
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