*New publication from EMSR* Osmotic energy, an infinite, clean energy source, can be efficiently harnessed through reverse electrodialysis using ion-selective membranes. While polymeric membranes are excellent candidates due to their solution-processability and scalability, their non-uniform pore architecture and high resistance limit their power density output. Here, an in situ space-confined synthesis strategy is proposed to fabricate sulfonated covalent organic frameworks within a sulfonated polymeric network, resulting in interconnected, well-defined ion channels. This allows a maximum power density reaching up to 40.33 W m⁻² under a 500-fold salinity gradient and a real-world power density of 14.84 W m⁻² when extracting osmotic energy from natural seawater and river water. This study underscores the potential of space-confined synthesis strategies in creating flexible and scalable ion-selective membranes for efficient salinity gradient energy harvesting, marking a significant step toward their practical applications.

Space-Confined Synthesis of Sulfonated Covalent Organic Framework‒Polymer Membranes for Enhanced Osmotic Energy Conversion

Y. Guo, X. Sun, Q. Zhang, Z. Low, H. Wang, Y. Zhu, L. Jiang

Small, 2025, e08217