Performance of Single Nanopore and Multi‐Pore Membranes for Blue Energy

The salinity gradient power extracted from the mixing of electrolyte solutions at different concentrations through selective nanoporous membranes is a promising route to renewable energy. However, several challenges need to be addressed to make this technology profitable, one of the most relevant being the increase of the extractable power per membrane area. Here, the performance of asymmetric conical and bullet‐shaped nanopores in a 50 nm thick membrane are studied via electrohydrodynamic simulations, varying the pore radius, curvature, and surface charge. The output power reaches ~60 pW per pore for positively charged membranes (surface charge σw=160 mC/m2) and ~30 pW for negatively charges ones, σw=−160 mC/m2 and it is robust to minor variations of nanopore shape and radius. A theoretical argument that takes into account the interaction among neighbour pores allows to extrapolate the single‐pore performance to multi‐pore membranes showing that power densities from tens to hundreds of W/m2 can be reached by proper tuning of the nanopore number density and the boundary layer thickness. Our model for scaling single‐pore performance to multi‐pore membrane can be applied also to experimental data providing a simple tool to effectively compare different nanopore membranes in blue energy applications. Conical and bullet‐shaped nanopores in a 50 nm thick membrane are studied via electrohydrodynamic simulations to evaluate their suitabilty for salinity gradient power generation. The effect of concentration polarization is described by a theoretical model that allows to extrapolate the multi‐pore membrane performance from single‐pore data, showing that power densities ranging from tens to hundreds of W/m2 can be reached.