Developing advanced oil–water separation technology
is significant
for environmental conservation. According to the synergetic effects
of the size-sieving mechanism, superwetting materials with small pore
sizes have been designed to realize high-efficiency separation for
oil–water emulsions. However, the separation flux limited by
the pore size and the weakness of the superwetting material impede
its practical application severely. Herein, we construct a robust
Janus superwetting textile with large pore sizes for oil-in-water
emulsion separation. The pristine textile is coated by the as-prepared
CuO nanoparticles as the bottom layer with superhydrophilicity and
then grafted by 1-octadecanethiol as the top layer with superhydrophobicity
to construct the Janus textile. When used as a filter, the superhydrophobic
layer acts as the nucleation site to coalesce the small oil droplets
facilely. Then, the coalesced oil fills the pores of the superhydrophobic
layer and selectively permeates it but is blocked by the superhydrophilic
layer with large pore sizes. Utilizing the unique separation mechanism,
the Janus textile realizes efficient and rapid separation. Even after
multicycle separation, hot liquid immersion for 24 h, tribological
test for 60 min, and sandpaper abrasion for 500 cycles, the Janus
textile still retains the superwettability and excellent separation
performance, manifesting outstanding stability to resist severe damage.
This separation strategy provides a novel guideline for high-efficiency
and high-flux emulsion separation and practical application.