posted on 2016-03-23, 00:00authored byHarim Jeon, Dong Jun Kim, Min Su Park, Du Yeol Ryu, Jong Hak Kim
Colloidal
nanosphere self-assembly effectively generates ordered nanostructures,
prompting tremendous interest in many applications such as photonic
crystals and templates for inverse opal fabrication. Here we report
the self-assembly of low-cost, graft copolymer nanospheres for CO2 capture membranes. Specifically, poly(dimethylsiloxane)-graft-poly(4-vinylpyridine) (PDMS-g-P4VP)
is synthesized via one-pot, free radical dispersion polymerization
to give discrete monodisperse nanospheres. These nanospheres comprise
a surface-anchored highly permeable PDMS layer and internal CO2-philic P4VP spherical core. Their diameter is controllable
below the submicrometer range by varying grafting ratios. The colloidal
dispersion forms a long-range, close-packed hexagonal array on a substrate
by inclined deposition and convective assembly. The array shows dispersion
medium-dependent packing characteristics. A thermodynamic correlation
is determined using different solvents to obtain stable PDMS-g-P4VP dispersions and interpreted in terms of Flory–Huggins
interaction parameter. As a proof-of-concept, the implementation of
these nanospheres into membranes simultaneously enhances the CO2 permeability and CO2/N2 selectivity
of PDMS-based transport matrixes. Upon physical aging of the solution,
the CO2/N2 selectivity is improved up to 26,
one of the highest values for highly permeable PDMS-based polymeric
membranes.