Nanofiltration membranes with bespoke porous architectures enable ultra-selective and energy-efficient separation of complex mixtures.

High value metals, such as lithium, could be extracted directly from seawater, lake brines, or could be recycled from electronic waste, a study of designer nanoporous membranes suggests. The membranes incorporate ring-shaped ‘macrocycle’ molecules, which form precisely defined pores that permit only the target metal to passarticle " id="return-reference-1" href="https://discovery.kaust.edu.sa/en/article/25238/precision-separations-with-perfect-pores/#reference-1">[1]. Macrocycle membranes can also efficiently purify challenging mixtures of high value chemicals, such as pharmaceutical ingredients, the KAUST research team has shownarticle " id="return-reference-2" href="https://discovery.kaust.edu.sa/en/article/25238/precision-separations-with-perfect-pores/#reference-2">[2].

Separating multicomponent mixtures is a core part of industrial activity ranging from raw minerals processing to fine chemical and pharmaceutical production. These steps have a large environmental footprint, however. Most separations involve energy-intensive heat-driven processes such as distillation and evaporation. “More effective separation methods would lead to a much more sustainable and profitable chemical industry, reducing the need for carbon capture at the end of the process,” says Suzana Nunes, who led the research.

“It is crucial to develop new materials that enable more efficient separations,” says Gyorgy Szekely, who co-led part of the work. A few industries – notably, seawater desalination – have employed membranes as an energy-efficient alternative to heat-driven separations. The membranes they use consist of tightly woven thin polymer sheets, through which water molecules can squeeze but salt cannot.

“Commercial membranes mostly separate water from salt, or separate large solutes from very small ones,” Nunes says. But because these membranes lack precisely defined pores, they are ineffective for finer-grained separations, she adds.

To efficiently separate mixtures of similarly sized molecules, Nunes and her colleagues developed membranes that incorporate ring-shaped macrocycles into their structure. “The macrocycles can act as a pore, tuned specifically for the size of molecule or ion to be transported,” Nunes says.

The team’s first challenge was to develop a versatile and scalable method for making membranes featuring embedded macrocycle, Szekely notes. The researchers were able to adapt an existing method that industry already uses to manufacture membranes, called interfacial polymerization.

This highlights the team’s pragmatism to enable easy industrial uptake. “Our focus is to invest in methods and materials that could fabricated at the scales required by industry,” Nunes says.

Read more at KAUST Discovery.