Abstract
Selective permeation through graphene nanopores is attracting increasing interest as an efficient and cost-effective technique for water desalination and purification. In this work, using umbrella sampling and molecular dynamics simulations with constant electric field, we analyze the influence of pore charge on potassium and chloride ion permeation. As pore charge is increased, the barrier of the potential of mean force (PMF) gradually decreases until it turns into a well split in two subminima. While in the case of K+ this pattern can be explained as an increasing electrostatic compensation of the desolvation cost, in the case of Cl− the pattern can be attributed to the accumulation of a concentration polarization layer of potassium ions screening pore charge. The analysis of potassium PMFs in terms of forces revealed a conflicting influence on permeation of van der Waals and electrostatic forces that both undergo an inversion of their direction as pore charge is increased. Even if the most important transition involves the interplay between the electrostatic forces exerted by graphene and water, the simulations also revealed an important role of the changing distribution of potassium and chloride ions. The influence of pore charge on the orientation of water molecules was also found to affect the van der Waals forces they exert on potassium.
Highlights
Graphene is a thin membrane consisting of sp2-bonded carbon atoms arranged in a honeycomb lattice.[1]
In this work, using umbrella sampling and molecular dynamics simulations with constant electric field, we analyze the influence of pore charge on potassium and chloride ion permeation
As pore charge is increased, the barrier of the potential of mean force (PMF) gradually decreases until it turns into a well split in two subminima
Summary
Graphene is a thin membrane consisting of sp2-bonded carbon atoms arranged in a honeycomb lattice.[1] Due to its peculiar structure, graphene is endowed with excellent thermal[2] and electric conduction properties[3] which make it widely used in energy storage devices like supercapacitors[4] and Li-ion batteries.[5] using electron beam irradiation[6] or block copolymer lithography[7] it is possible to drill nanoscale pores in a single graphene layer This technology paves the way to a wide range of potential applications in the elds of desalination of seawater,[8] wastewater puri cation[9] and DNA sequencing.[10] These applications take advantage of the ultrathinness of graphene which allows fast water transport while excluding ions or selecting speci c ion types. Signi cant advances in this eld have been achieved by Gilbert
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
