posted on 2016-01-19, 00:00authored byMeng Hu, Sunxiang Zheng, Baoxia Mi
This
study provides experimental evidence to mechanistically understand
some contradicting effects of the characteristic properties of graphene
oxide (GO), such as the high hydrophilicity, negative charge, strong
adsorption capability, and
large surface area, on the antifouling properties of GO membranes.
Furthermore, this study demonstrates the effectiveness of forming
a dense GO barrier layer on the back (i.e., porous) side of an asymmetric
membrane for fouling control in pressure-retarded osmosis (PRO), an
emerging engineered osmosis process whose advancement
has been much hindered due to the severe irreversible fouling that
occurs as foulants accumulate inside the porous membrane support. In the membrane fouling experiments, protein and alginate were used as model organic foulants. When operated
in forward osmosis mode, the GO membrane exhibited fouling performance
comparable with that of a polyamide (PA) membrane. Analysis of the
membrane adsorption capacity showed that, likely due to the presence
of hydrophobic regions in the GO basal plane, the GO membrane has
an affinity toward organic foulants 4 to 5 times higher than the PA
membrane. Such a high adsorption capacity along with a large surface
area, however, did not noticeably aggravate the fouling problem. Our
explanation for this phenomenon is that organic foulants are adsorbed
mainly on the basal plane of GO nanosheets, and water enters the GO
membrane primarily around the oxidized edges of GO, making foulant
adsorption not create much hindrance to water flux. When operated
in PRO mode, the GO membrane exhibited much better antifouling performance
than the PA membrane. This is because unlike the PA membrane for which
foulants can be easily trapped inside the porous support and hence
cause severe irreversible fouling, the GO membrane allows the foulants
to accumulate primarily on its surface due to the sealing effect of
the GO layer assembled on the porous side of the asymmetric membrane
support. Results from the physical cleaning experiments further showed
that the water flux of GO membranes operated in PRO mode can be sufficiently
restored toward its initial prefouling level.