posted on 2022-06-17, 16:34authored byYadong Wu, Haoyang Ling, Yongchao Qian, Yuhao Hu, Bo Niu, Xiangbin Lin, Xiang-Yu Kong, Lei Jiang, Liping Wen
Membrane separation provides effective
methods for solving the
global water crisis. Contemporary membrane systems depend on interfacial
interactions between liquid and solid membrane matrixes. However,
it may lead to a limiting permeate flux due to the large flow resistance
at hydrophobic liquid–solid interfaces. Herein, the liquid–liquid
interface with improved interface energy is reversibly introduced
in membrane systems to boost wetting and reduce transport resistance.
A series of interfaces were systematically explored to reveal mechanisms
of wetting and boosted flow performances, which are further supported
by simulations. Findings of this study highlight that interfacial
liquids with lower surface energies, lower viscosities, and higher
solubilities can effectively improve water flow without sacrificing
rejection performance, achieving by transforming a solid–liquid
interface into liquid–liquid interface interaction. It provides
a concept to design advanced membrane systems for water purification
(e.g., desalination and oil–water separation)
and energy conversion processes.