Porous nanosheets combined with polymers can remove contaminants from methane.
Natural gas is the world’s main source of methane
, widely used as a fuel and a chemical feedstock, but it often contains unwanted gases such as hydrogen sulfide and carbon dioxide. KAUST researchers have now developed a membrane that can remove these contaminants in a much more energy-efficient way than conventional processes that rely on chemical washes.
The membrane is based on a crystalline metal-organic framework (MOF) material. MOFs contain pores that can be tailored to allow certain gas molecules to pass through while blocking others. In principle, MOFs could be used with flexible, robust polymers to produce practical separation membranes, but until now it has been difficult to unite the materials without curtailing their desirable properties.
To solve this problem, the KAUST team developed a new three-part strategy to bring a MOF and a polymer together into a mixed-matrix metal-organic framework (MMMOF) membrane. First, the researchers identified a MOF, called KAUST-8, whose pores form tiny channels that are large enough to fit molecules of hydrogen sulfide and carbon dioxide but not methane.
The MOF’s pores form tiny channels that are aligned in one direction through the crystal. The researchers carefully grew their MOFs into flat nanosheets, so that the channels ran from one face of the sheet to the other.
Finally, the researchers sandwiched thousands of these nanosheets between layers of a robust polyimide polymer. The nanosheets were oriented so that their channels all lay in the same direction. This ensured that contaminant gases could easily pass through multiple nanosheets and travel from one side of the 50-70 micrometer-wide membrane to the other.
Read the full story at KAUST Discovery.