We
report the comparative aggregation behavior of three emerging
inorganic 2D nanomaterials (NMs): MoS2, WS2,
and h-BN in aquatic media. Their aqueous dispersions were subjected
to aggregation under varying concentrations of monovalent (NaCl) and
divalent (CaCl2) electrolytes. Moreover, Suwanee River
Natural Organic Matter (SRNOM) has been used to analyze the effect
of natural macromolecules on 2D NM aggregation. An increase in electrolyte
concentration resulted in electrical double-layer compression of the
negatively charged 2D NMs, thus displaying classical Derjaguin–Landau–Verwey–Overbeek
(DLVO)-type interaction. The critical coagulation concentrations (CCC)
have been estimated as 37, 60, and 19 mM NaCl and 3, 7.2, and 1.3
mM CaCl2 for MoS2, WS2, and h-BN,
respectively. Theoretical predictions of CCC by modified DLVO theory
have been found comparable to the experimental values when dimensionality
of the materials is taken into account and a molecular modeling approach
was used for calculating molecular level interaction energies between
individual 2D NM nanosheets. Electrostatic repulsion has been found
to govern colloidal stability of MoS2 and WS2 while the van der Waals attraction has been found to govern that
of h-BN. SRNOM stabilizes the 2D NMs significantly possibly by electrosteric
repulsion. The presence of SRNOM completely stabilized MoS2 and WS2 at both low and high ionic strengths. While h-BN
still showed appreciable aggregation in the presence of SRNOM, the
aggregation rates were decreased by 2.6- and 3.7-fold at low and high
ionic strengths, respectively. Overall, h-BN nanosheets will have
higher aggregation potential and thus limited mobility in the natural
aquatic environment when compared to MoS2 and WS2. These results can also be used to mechanistically explain fate,
transport, transformation, organismal uptake, and toxicity of inorganic
2D NMs in the natural ecosystems.
Peracetic acid (PAA) is being considered as a disinfectant in membrane-based wastewater reuse systems. This study shows that PAA is overall compatible with polyamide membranes and proposes PAA-polyamide reaction mechanisms.
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