posted on 2020-12-14, 20:34authored byNicholas Hampu, Jay R. Werber, Wui Yarn Chan, Elizabeth C. Feinberg, Marc A. Hillmyer
Reliable
and equitable access to safe drinking water is a major
and growing challenge worldwide. Membrane separations represent one
of the most promising strategies for the energy-efficient purification
of potential water sources. In particular, porous membranes are used
for the ultrafiltration (UF) of water to remove contaminants with
nanometric sizes. However, despite exhibiting excellent water permeability
and solution processability, existing UF membranes contain a broad
distribution of pore sizes that limit their size selectivity. To maximize
the potential utility of UF membranes and allow for precise separations,
improvements in the size selectivity of these systems must be achieved.
Block polymers represent a potentially transformative solution, as
these materials self-assemble into well-defined domains of uniform
size. Several different strategies have been reported for integrating
block polymers into UF membranes, and each strategy has its own set
of materials and processing considerations to ensure that uniform
and continuous pores are generated. This Review aims to summarize
and critically analyze the chemistries, processing techniques, and
properties required for the most common methods for producing porous
membranes from block polymers, with a particular focus on the fundamental
mechanisms underlying block polymer self-assembly and pore formation.
Critical structure–property–performance metrics will
be analyzed for block polymer UF membranes to understand how these
membranes compare to commercial UF membranes and to identify key research
areas for continued improvements. This Review is intended to inform
readers of the capabilities and current challenges of block polymer
UF membranes, while stimulating critical thought on strategies to
advance these technologies.