Crystal orientation control in angstrom-scale channel membranes for significantly enhanced blue energy harvesting

[Display omitted] •Crystal orientation in MOF membranes is precisely controlled and shown for enhanced blue energy.•Preferred crystal orientation in MOF membranes is characterized via 2D GIWAXS.•Oriented MIL-178 membrane shows faster ion transport and higher cation selectivity.•An unprecedented power of 9.64 W/m2 with an efficiency 38.5 % is reached by mixing seawater/river waters. Achieving high-performance blue energy harvesting from the interface between seawater and river water remains challenging, because the current ion-selective membrane suffers from a trade-off between ion permeability and selectivity. Here, we tackle this issue by manipulating the crystal orientations within metal–organic framework (MOF) MIL-178 membranes, including one with the a-axis perpendicular to the substrate, and the other with the b-axis similarly configured. We show that the MIL-178-a-oriented membrane exhibited over one order of magnitude faster ion transport than the MIL-178-b-oriented membrane, and one-dimensional angstrom-scale (∼3.2 Å) channels endow the former with ultrahigh ion selectivity. Consequently, the MIL-178-a-oriented membrane achieves an ultrahigh power density of ∼9.64 W/m2, with an unprecedented energy conversion efficiency of ∼38.5 % approaching the theoretical upper limit of 50 %, when simulated seawater and river water are mixed, surpassing all the reported non-oriented MOF-based membranes. This study presents a method for finely tuning preferred orientations within polycrystalline MOF membranes, enabling precise engineering of ultrahigh-performance osmotic energy conversion.