posted on 2016-09-20, 00:00authored byKai Xiao, Yahong Zhou, Xiang-Yu Kong, Ganhua Xie, Pei Li, Zhen Zhang, Liping Wen, Lei Jiang
Regulating
and controlling the transport of water across nanochannels is of great
importance in both fundamental research and practical applications
because it is difficult to externally control water flow through nanochannels
as in biological channels. To date, only a few hydrophobic nanochannels
controlling the transport of water have been reported, all of which
use exotic hydrophobic molecules. However, the effect of electrostatic
charges, which plays an indispensable role in membrane proteins and
dominates the energetics of water permeation across aquaporins, has
not gained enough attention to control water transport through a solid-state
nanochannel/nanopore. Here, we report electrostatic-charge-induced
water gating of a single ion track-etched sub-10 nm channel. This
system can directly realize the gating transition between an open,
conductive state and a closed, nonconductive state by regulating the
surface charge density through a process that involves alternating
capillary evaporation and capillary condensation. Compared to the
introduction of exotic hydrophobic molecules, water gating controlled
by electrostatic charges is simple, convenient, and effective. Such
a system anticipates potential applications including desalination,
controllable valves, and drug delivery systems.