posted on 2021-04-13, 00:43authored byGuangyan Chen, Baicun Hao, Yujia Wang, Yanan Wang, Hanzhong Xiao, Huifang Li, Xin Huang, Bi Shi
Industrial manufacture generates
a huge quantity of emulsion wastewater,
which causes serious threats to the aquatic ecosystems. Water-in-oil
(W/O) and oil-in-water (O/W) emulsions are two major types of emulsions
discharged by industries. However, dual separation of W/O and O/W
emulsions remains a challenging issue due to the contradictory permselectivity
for separating the two emulsions. In the present investigation, the
amphiphilicity-derived regional wetting mechanism of water and oil
on the amphiphilic collagen fibers was revealed based on the combination
of numerous experiments and molecular dynamics (MD) simulations. Electrostatic
interactions and van der Waals force were manifested to be the driving
forces of regional wetting in the hydrophilic and hydrophobic regions,
respectively. The regional wetting endowed amphiphilic collagen fibers
with underwater oleophobicity and underoil hydrophilicity, which enabled
dual separation of emulsions by selectively retaining the dispersed
water phase of W/O emulsions in the hydrophilic regions while the
dispersed oil phase of O/W emulsions in the hydrophobic regions. The
achieved separation efficiency was higher than 99.98%, and the flux
reached 3337.6 L m–2 h–1. Initial
wetting status significantly affects the regional wetting-enabled
dual separation. Based on the MD simulations, amphiphilic intramolecular
conformations of tropocollagen were suggested to be the origins of
regional wetting on collagen fibers. Our findings may pave the way
for developing high-performance dual separation materials that are
promising to be utilized for the practical treatment of emulsion wastewater.