Separation processes constitute a highly important tool in our efforts to mitigate CO2 emissions. However, today’s separations are tremendously energy intensive, (separating various gases accounts for ~15% of the total global energy consumption), and they don’t achieve the desired performance for CO2-related separations. Zeolitic imidazolate frameworks (ZIFs) in the form of membranes, are studied towards developing cheaper, and better performing separation methods. Their most fascinating aspect is their modification and/or functionalization capabilities: ZIFs can be modified on the molecular level, and this can potentially provide control on their macroscopic properties. In other words, someone could tailor their separation performance by applying the appropriate changes in their framework (i.e. by using optimal variants of the ZIF building blocks). However, the correlation between the molecular structural changes and their subsequent ZIF separation efficiency is a very complex correlation that is yet to be resolved. Unveiling this correlation is very important, since it is expected that proper implementation of such materials in separation processes can have a huge impact on the global economy as well as on our effectiveness in reducing CO2 emissions.
In this project the main objective was to unmask the missing modification-separation correlation in ZIFs. Modification comes in the form of replacing the structural sub-units of the framework. Regarding the separation performance, we focused on the diffusivity of gases ZIFs, since this is the main driving force in separations with such materials. First, a novel artificial intelligence (AI) tool was developed, that is the first-reported tool that can predict the diffusivity of any gas in any known or un-known ZIF, as long as a researcher-user knows simple and readily available information about the ZIF structure under consideration. Then, with the help of this AI tool we were able to identify highly performing ZIFs for three highly challenging, CO2-related separations: H2/CO2, CO2/N2 and CO2/CH4. Finally, a new approach based on genetic algorithms was used and a software that can construct and propose optimal ZIF structures was developed.