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On the Order and Orientation in Liquid Crystalline Polymer Membranes for Gas Separation

[Image: see text] To prevent greenhouse emissions into the atmosphere, separations like CO(2)/CH(4) and CO(2)/N(2) from natural gas, biogas, and flue gasses are crucial. Polymer membranes gained a key role in gas separations over the past decades, but these polymers are often not organized at a mole...

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Detalles Bibliográficos
Autores principales: Kloos, Joey, Jansen, Nico, Houben, Menno, Casimiro, Anna, Lub, Johan, Borneman, Zandrie, Schenning, Albert P.H.J., Nijmeijer, Kitty
Formato: Online Artículo Texto
Lenguaje:English
Publicado: American Chemical Society 2021
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8587323/
https://www.ncbi.nlm.nih.gov/pubmed/34776611
http://dx.doi.org/10.1021/acs.chemmater.1c02526
Descripción
Sumario:[Image: see text] To prevent greenhouse emissions into the atmosphere, separations like CO(2)/CH(4) and CO(2)/N(2) from natural gas, biogas, and flue gasses are crucial. Polymer membranes gained a key role in gas separations over the past decades, but these polymers are often not organized at a molecular level, which results in a trade-off between permeability and selectivity. In this work, the effect of molecular order and orientation in liquid crystals (LCs) polymer membranes for gas permeation is demonstrated. Using the self-assembly of polymerizable LCs to prepare membranes ensures control over the supramolecular organization and alignment of the building blocks at a molecular level. Robust freestanding LC membranes were fabricated that have various, distinct morphologies (isotropic, nematic cybotactic, and smectic C) and alignment (planar and homeotropic), while using the same chemical composition. Single gas permeation data show that the permeability decreases with increasing molecular order while the ideal gas selectivity of He and CO(2) over N(2) increases tremendously (36-fold for He/N(2) and 21-fold for CO(2)/N(2)) when going from randomly ordered to the highly ordered smectic C morphology. The calculated diffusion coefficients showed a 10-fold decrease when going from randomly ordered membranes to ordered smectic C membranes. It is proposed that with increasing molecular order, the free volume elements in the membrane become smaller, which hinders gasses with larger kinetic diameters (Ar, N(2)) more than gasses with smaller kinetic diameters (He, CO(2)), inducing selectivity. Comparison of gas sorption and permeation performances of planar and homeotropic aligned smectic C membranes shows the effect of molecular orientation by a 3-fold decrease of the diffusion coefficient of homeotropic aligned smectic C membranes resulting in a diminished gas permeation and increased ideal gas selectivities. These results strongly highlight the importance of molecular order and orientation in LC polymer membranes for gas separation.