Giant osmotic energy conversion measured in a single transmembrane boron nitride nanotube

A very large, osmotically induced electric current is generated by a salinity gradient between the ends of a single boron nitride transmembrane nanotube, owing to the anomalously high surface charge carried by the nanotube’s internal surface in water at large pH. Osmotic energy from a BN nanotube membrane This paper describes the fabrication of a new type of nanopore membrane, in which a single boron nitride nanotube traverses an ultrathin silicon nitride membrane. The platform allows an exploration of the effects of pressure, chemical gradients and electric fields on fluidic transport at the nanoscale. In addition, it suggests a possible route to new technologies capable of producing large amounts of electric power from salinity gradients. Reservoirs on each side of the membrane contain different potassium chloride concentrations, generating a salinity gradient across the nanotube. This gradient results in the generation of a large osmotically driven electric current that the authors attribute to a large surface charge carried by the internal walls of the nanotube in water at high pH. New models of fluid transport are expected to emerge from the confinement of liquids at the nanoscale 1 , 2 , with potential applications in ultrafiltration, desalination and energy conversion 3 . Nevertheless, advancing our fundamental understanding of fluid transport on the smallest scales requires mass and ion dynamics to be ultimately characterized across an individual channel to avoid averaging over many pores. A major challenge for nanofluidics thus lies in building distinct and well-controlled nanochannels, amenable to the systematic exploration of their properties. Here we describe the fabrication and use of a hierarchical nanofluidic device made of a boron nitride nanotube that pierces an ultrathin membrane and connects two fluid reservoirs. Such a transmembrane geometry allows the detailed study of fluidic transport through a single nanotube under diverse forces, including electric fields, pressure drops and chemical gradients. Using this device, we discover very large, osmotically induced electric currents generated by salinity gradients, exceeding by two orders of magnitude their pressure-driven counterpart. We show that this result originates in the anomalously high surface charge carried by the nanotube’s internal surface in water at large pH, which we independently quantify in conductance measurements. The nano-assembly route using nanostructures as building b