Bioinspired Macrocyclic Molecule Supported Two-Dimensional Lamellar Membrane with Robust Interlayer Structure for High-Efficiency Nanofiltration

2D lamellar membranes (2DLMs) are used for efficient desalination and nanofiltration. However, weak interactions between adjacent stacked nanosheets result in susceptibility to swelling that limits practical applicability. Inspired by the super adhesion of multi-point suction cups on octopus tentacles, a 2DLM is constructed from Ti3C2Tx MXene supported by the macrocyclic multi-point molecule cucurbit[5]uril (CB5) and demonstrated for nanofiltration of methyl blue (MB) and enrichment of uranyl carbonate. Experimental results and density functional theory calculations indicate that CB5 rivets to the surface of the nanoflakes through strong stable interactions between its multiple binding sites and surface hydroxyl functional groups on MXene nanosheets. This novel 2DLM exhibits excellent nanofiltration performance (69 L m(-2)h(-1)bar(-1) permeance with 93.6% rejection for MB) and can be recycled at least 30 times without significant degradation. The 2DLM exhibits excellent swelling resistance at high salinity, with a demonstration of selective enrichment of uranyl carbonate from artificial water and natural seawater. The results provide a new strategy for constructing highly stable 2DLMs with interlayer spacing controllable from sub-nano to nanometer scales, for size-selective sieving of molecules and ions, high-efficiency nanofiltration, and other applications.

Automated summary

Inspired by the super adhesion of multi-point suction cups on octopus tentacles, researchers constructed a 2D lamellar membrane (2DLM) from Ti3C2Tx MXene supported by the macrocyclic multi-point molecule cucurbit[5]uril (CB5). The 2DLM exhibited excellent nanofiltration performance and swelling resistance at high salinity, and it could be recycled at least 30 times without significant degradation. This novel membrane provides a new strategy for constructing highly stable 2DLMs for various applications.