Role of ring-size and side-chain length in artificial water channel permeability

Membranes are an integral part to the water-energy nexus and produce approximately 142 billion liters of desalinated water per day. A common trade-off observed in reverse osmosis membranes is an exchange between permeability and ion rejection (>99%). One such solution to overcome this upper bound is inspired by biological membranes that display high rejection and high permeability. Synthetic transmembrane channels mimic the function of aquaporin protein channels by promoting one-dimensional water transport and selectively transporting water via angstrom scale pores. We investigate one such synthetic channel architecture, ligand-appended pillarene, to evaluate how design parameters within the channel chemistry, such as channel ring-size (m=5,6), appended-ligand length (n=4,6,8), and appended chemistry, impacts the permeability of these synthetic channels.