posted on 2019-02-16, 00:00authored byJian Ma, Kun Li, Zhongwu Li, Yinghua Qiu, Wei Si, Yanyan Ge, Jingjie Sha, Lei Liu, Xiao Xie, Hong Yi, Zhonghua Ni, Deyu Li, Yunfei Chen
Ion transport through
nanopores is a process of fundamental significance
in nature and in engineering practice. Over the past decade, it has
been found that the ion conductivity in nanopores could be drastically
enhanced, and different mechanisms have been proposed to explain this
observation. To date, most reported studies have been carried out
with relatively dilute electrolytes, while ion transport in nanopores
under high electrolyte concentrations (>1 M) has been rarely explored.
Through systematic experimental and atomistic simulation studies with
NaCl solutions, here we show that at high electrolyte concentrations,
ion mobility in small nanopores could be significantly reduced from
the corresponding bulk value. Subsequent molecular dynamics studies
indicate that in addition to the low mobility of surface-bound ions
in the Stern layer, enhanced pairing and collisions between partially
dehydrated ions of opposite charges also make important contributions
to the reduced ion mobility. Furthermore, we show that the extent
of mobility reduction depends on the association constant between
cations and anions in different electrolytes with a more drastic reduction
for a larger association constant.