Lamellar porous vermiculite membranes for boosting nanofluidic osmotic energy conversion

Lamellar membranes with two-dimensional nanofluidic channels hold great promise in harvesting osmotic energy from salinity gradients. However, the power density is often limited by the high transmembrane resistance primarily caused by the tortuous interlayer ion diffusion pathway. Here, we demonstrate the great potential of lamellar porous vermiculite membranes (PVMs) as efficient nanofluidic osmotic energy generators. The artificial in-plane nanopores on vermiculite nanosheets dramatically decrease the tortuosity and offer additional vertical ion pathways, substantially elevating the transmembrane ion flux. Meanwhile, the confined interlayer spacing serves as the selective barrier, contributing to a high ion selectivity. When operating under a 1000-fold salinity gradient, the PVMs achieve a 16-fold increase in output power density compared with nonporous vermiculite membranes, with a maximum value of 10.9 W m(-2) that outperforms those of most of the state-of-the-art 2D lamellar membranes.

Automated summary

Lamellar porous vermiculite membranes show great potential as efficient nanofluidic osmotic energy generators, with artificial nanopores and selective barriers contributing to high ion flux and selectivity, resulting in a significant increase in output power density compared to nonporous membranes.