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Materials design by evolutionary optimization of functional groups in metal-organic frameworks

Published version
Peer-reviewed

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Authors

Collins, SP 
Daff, TD 
Piotrkowski, SS 
Woo, TK 

Abstract

A genetic algorithm that efficiently optimizes a desired physical or functional property in metal-organic frameworks (MOFs) by evolving the functional groups within the pores has been developed. The approach has been used to optimize the CO₂ uptake capacity of 141 experimentally characterized MOFs under conditions relevant for postcombustion CO₂ capture. A total search space of 1.65 trillion structures was screened, and 1035 derivatives of 23 different parent MOFs were identified as having exceptional CO₂ uptakes of >3.0 mmol/g (at 0.15 atm and 298 K). Many well-known MOF platforms were optimized, with some, such as MIL-47, having their CO₂ adsorption increase by more than 400%. The structures of the high-performing MOFs are provided as potential targets for synthesis.

Description

Keywords

Metal organic frameworks, carbon capture, functionalization, genetic algorithm, materials design, molecular simulation, nanoporous materials, virtual screening

Journal Title

Science Advances

Conference Name

Journal ISSN

2375-2548
2375-2548

Volume Title

2

Publisher

AAAS
Sponsorship
: We thank the Natural Sciences and Engineering Research Council of Canada, Carbon Management Canada, and Canada Research Chairs Program for financial support and Compute Canada and the Canada Foundation for Innovation for computing resources