posted on 2019-04-11, 00:00authored byZhe Yang, Hao Guo, Zhi-kan Yao, Ying Mei, Chuyang Y. Tang
Thin-film nanocomposite
(TFN) membranes have been widely studied
over the past decade for their desalination applications. For some
cases, the incorporation of nonporous hydrophilic nanofillers has
been reported to greatly enhance membrane separation performance,
yet the underlying mechanism is poorly understood. The current study
systematically investigates TFN membranes incorporated with silver
nanoparticles (AgNPs). For the first time, we reveal the formation
of nanochannels of approximately 2.5 nm in size around the AgNPs,
which can be attributed to the hydrolysis of trimesoyl chloride monomers
and thus the termination of interfacial polymerization by the water
layer around each hydrophilic nanoparticle. These nanochannels nearly
tripled the membrane water permeability for the optimal membrane.
In addition, this membrane showed increased rejection against NaCl,
boron, and a set of small-molecular organic compounds (e.g., propylparaben,
norfloxacin, and ofloxacin), thanks to its combined effects of improved
size exclusion, enhanced Donnan exclusion, and suppressed hydrophobic
interaction. Our work provides fundamental insights into the formation
and transport mechanisms involved in solid-filler incorporated TFN
membranes. Future studies should take advantage of this spontaneous
nanochannel formation in the design of TFN to overcome the classical
membrane permeability–selectivity trade-off.