Anomalous solid-like necking of confined water outflow in hydrophobic nanopores

TL;DR: In this article , through an extensive set of molecular dynamics simulations of supercooled bulk and interfacial water films and nano-droplets, the authors observed the formation of persistent, spatially extended dynamical domains in which the average mobility varies as a function of the distance from the interface.

TL;DR: In this paper , the interaction between ions and water molecules in a hydrophobic nanopore forms a coordination network with an interaction density that is nearly four-fold as that of the bulk counterpart.

TL;DR: In this paper , a soft-matter-inspired approach is proposed based on the spontaneous formation of a molecularly thin liquid film onto fully wettable substrates in contact with the vapor phase of the liquid.

TL;DR: Gas and water flow measurements through microfabricated membranes in which aligned carbon nanotubes with diameters of less than 2 nanometers serve as pores enable fundamental studies of mass transport in confined environments, as well as more energy-efficient nanoscale filtration.

TL;DR: Several similar models are considered with the additional constraint of trying to match the performance of the optimized potentials for liquid simulation atom force field to that obtained when using the simulation conditions under which it was originally designed, but no model was entirely satisfactory in reproducing the relative difference in free energies of hydration between the model compounds, phenol and benzene.

TL;DR: In this paper, the authors reviewed the basic characteristics of the liquid-glass transition, emphasizing its universality and briefly summarizing the most popular phenomenological models, focusing on a number of alternative models which one way or the other connect the fast and slow degrees of freedom of viscous liquids.

TL;DR: The fabrication and use of a hierarchical nanofluidic device made of a boron nitride nanotubes that pierces an ultrathin membrane and connects two fluid reservoirs is described, which allows the detailed study of fluidic transport through a single nanotube under diverse forces, including electric fields, pressure drops and chemical gradients.