Abstract
Lamellar membranes obtained by stacking 2D layers possess ample transport pathways due to their intricate network of interlayer gaps. This makes them suitable for molecular separation applications. However, controlling the surface chemistry of the nanochannels within the membrane to tune the desired transport properties of water and ions is challenging. Ti(3)C(2)T (x) has been considered for water desalination because of its hydrophilic surface and negative surface charge. Most of the studies of Ti(3)C(2)T (x) membranes have presented promising salt rejection values in forward osmosis mode, which is less practical for water purification. Here, we investigate two types of reverse osmosis MXene-based lamellar membranes consisting of Ti(3)C(2)T (x) nanosheets hybridized with (i) WS(2) nanosheets and (ii) polyvinyl phosphonic acid (PVPA). When hydrophilic and flexible Ti(3)C(2)T (x) nanosheets are interleaved with softer and more hydrophobic WS(2) nanosheets in 2 : 1 mass ratio, nano capillaries with Janus chemistry are created with comparable rejection to bare Ti(3)C(2)T (x) membrane and threefold higher permeance values. Further, we find that decorating Ti(3)C(2)T (x) nanosheets with anionic polymers improves salt rejection. Our Ti(3)C(2)T (x) /PVPA composite membranes reject ∼97% of divalent ions and ∼80% of monovalent ions with ∼0.2 Lm(-2) h(-1) bar(-1) of water permeance when tested with brackish water, and exhibit significantly improved chlorine resistance and cost benefits over the commercial Toray membranes.