posted on 2022-08-03, 19:38authored byXinke Zhang, Shuang Li, Jiaye Su
Reverse osmosis membranes hold great promise for dealing
with global
water scarcity. However, the trade-off between ion selectivity and
water permeability is a serious obstacle to desalination. Herein,
we introduce an effective strategy to enhance the desalination performance
of the membrane. A series of molecular dynamics simulations manifest
that an additional lateral electric field significantly promotes ion
rejection in carbon nanotubes (CNTs) under the drive of longitudinal
pressure. Specifically, with the increase in the electric field, the
ion flux shows a deep linear decay, while the water flux decreases
only slightly, resulting in a linear increase in ion rejection. The
energy barriers of ions around the CNT inlet are obtained by calculating
the potentials of mean force to explain enhanced ion rejection. The
lateral electric field uniformly raises the energy barriers of ions
by pushing them away from the CNT inlet, corresponding to the enhanced
ion velocity in the field direction. Furthermore, with the increase
in CNT diameter, there is a significant increase in the flux of both
ions and water; however, the lateral electric field can also obviously
enhance the ion rejection in wider CNTs. Consequently, the enhancement
of ion rejection by lateral electric fields should be universal for
different CNT diameters, which opens a new avenue for selective permeation
and may have broad implications for desalination devices with large
pore sizes.