2D Heterostructured Nanofluidic Channels for Enhanced Desalination Performance of Graphene Oxide Membranes.

The two-dimensional (2D) lamellar membrane assembly technique shows substantial potential for sustainable desalination applications. However, the relatively wide and size-variable channels of 2D membranes in aqueous solution result in inferior salt rejections. Here we show the establishment of nanofluidic heterostructured channels in graphene oxide (GO) membranes by adding g-CN sheets into GO interlamination. Benefiting from the presence of stable and sub-nanometer wide (0.42 nm) GO/g-CN channels, the GO/g-CN membrane exhibits salt rejections of ∼90% with water permeances of above 30 L h m bar, while the pure GO membrane only has salt rejections of below 30% accompanied by water permeances of below 4 L h m bar. Combining experimental and theoretical investigations, size exclusion has proved to be the dominating mechanism for high rejections, and the ultralow friction water flow along g-CN sheets is responsible for permeation enhancements. Importantly, the GO/g-CN membrane shows promising long-term, antioxidation, and antipressure stability.