Cation-controlled wetting properties of vermiculite membranes and its promise for fouling resistant oil–water separation

Huang, Kan; Rowe, P.; Chi, C.; Sreepal, V.; Bohn, T.; Zhou, K.-G.; Su, Y.; Prestat, E.; Pillai, P. Balakrishna; Cherian, C. T.; Michaelides, A.; Nair, R. R.

Cation-controlled wetting properties of vermiculite membranes and its promise for fouling resistant oil–water separation

Kan Huang, P. Rowe, C. Chi, V. Sreepal, T. Bohn, K.-G. Zhou, Y. Su, E. Prestat, P. Balakrishna Pillai, C. T. Cherian (), A. Michaelides () and R. R. Nair ()
Additional contact information
P. Rowe: University College London
C. Chi: University of Manchester
V. Sreepal: University of Manchester
T. Bohn: University of Manchester
K.-G. Zhou: University of Manchester
Y. Su: University of Manchester
E. Prestat: University of Manchester
P. Balakrishna Pillai: University of Manchester
C. T. Cherian: University of Manchester
A. Michaelides: University College London
R. R. Nair: University of Manchester

Nature Communications, 2020, vol. 11, issue 1, 1-10

Abstract: Abstract Manipulating the surface energy, and thereby the wetting properties of solids, has promise for various physical, chemical, biological and industrial processes. Typically, this is achieved by either chemical modification or by controlling the hierarchical structures of surfaces. Here we report a phenomenon whereby the wetting properties of vermiculite laminates are controlled by the hydrated cations on the surface and in the interlamellar space. We find that vermiculite laminates can be tuned from superhydrophilic to hydrophobic simply by exchanging the cations; hydrophilicity decreases with increasing cation hydration free energy, except for lithium. The lithium-exchanged vermiculite laminate is found to provide a superhydrophilic surface due to its anomalous hydrated structure at the vermiculite surface. Building on these findings, we demonstrate the potential application of superhydrophilic lithium exchanged vermiculite as a thin coating layer on microfiltration membranes to resist fouling, and thus, we address a major challenge for oil–water separation technology.

Date: 2020
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DOI: 10.1038/s41467-020-14854-4

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