Litcius/Paper detail

Custom Formulation of Multicomponent Mixed-Matrix Membranes for Efficient Post-combustion Carbon Capture

Sameh K. Elsaidi, Surendar R. Venna, Ali Sekizkardes, Janice A. Steckel, Mona H. Mohamed, James S. Baker, John P. Baltrus, David Hopkinson

2020Cell Reports Physical Science17 citationsDOIOpen Access PDF

Abstract

Mixed-matrix membranes have great potential for post-combustion carbon capture. To make membrane-based carbon capture economically viable, new formulations with high selectivity and CO2 permeance must be identified. We demonstrate here the ability to break the permeability-selectivity trade-off by using multicomponent mixed-matrix membranes (McMMMs) with two, three, or four components. Each of these components has a specific function and is designed for compatibility and high separation performance. A highly permeable polymer of intrinsic microporosity, PIM-1, and a CO2-selective polyphosphazene polymer, MEEP80, are chosen as polymer matrices. Chemical interaction between MOF nanoparticles and polymers is a key factor for optimizing the MOF-polymer interfacial compatibility. The systematic study of the impact of MOF pore size and the binding site is investigated to produce 10 different composite membranes. The permeability-selectivity values surpass the Robeson upper bound, while the predicted cost of carbon capture is reduced, which suggests the potential of these membranes for practical CO2 separations.

Topics & Concepts

MembranePermeancePolymerSelectivityChemical engineeringBarrerMaterials scienceCompatibility (geochemistry)CombustionGas separationPolyphosphazenePolymer chemistryChemistryComposite materialOrganic chemistryPermeationEngineeringBiochemistryCatalysisMembrane Separation and Gas TransportMetal-Organic Frameworks: Synthesis and ApplicationsCovalent Organic Framework Applications