The development of a comprehensive toolbox based on multi-level, high-throughput screening of MOFs for CO/N2 separations

The separation of CO/N2 mixtures is a challenging problem in the petrochemical sector due to the very similar physical properties of these two molecules, such as size, molecular weight and boiling point. To solve this and other challenging gas separations, one requires a holistic approach. The compl...

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Veröffentlicht in:	Chemical science (Cambridge) 2021-09, Vol.12 (36), p.12068-12081
Hauptverfasser:	Rampal, Nakul, Abdulmalik Ajenifuja, Tao, Andi, Balzer, Christopher, Cummings, Matthew S, Evans, Arwyn, Bueno-Perez, Rocio, Law, David J, Bolton, Leslie W, Petit, Camille, Siperstein, Flor, Attfield, Martin P, Jobson, Megan, Moghadam, Peyman Z, Fairen-Jimenez, David
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Sprache:	eng
Schlagworte:	Adsorption Boiling points Carbon monoxide Chemistry Criteria Data mining Gas separation Industrial applications Metal-organic frameworks Morphology Multiscale analysis Physical properties Porous materials Screening
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creator	Rampal, Nakul Abdulmalik Ajenifuja Tao, Andi Balzer, Christopher Cummings, Matthew S Evans, Arwyn Bueno-Perez, Rocio Law, David J Bolton, Leslie W Petit, Camille Siperstein, Flor Attfield, Martin P Jobson, Megan Moghadam, Peyman Z Fairen-Jimenez, David
description	The separation of CO/N2 mixtures is a challenging problem in the petrochemical sector due to the very similar physical properties of these two molecules, such as size, molecular weight and boiling point. To solve this and other challenging gas separations, one requires a holistic approach. The complexity of a screening exercise for adsorption-based separations arises from the multitude of existing porous materials, including metal–organic frameworks. Besides, the multivariate nature of the performance criteria that needs to be considered when designing an optimal adsorbent and a separation process – i.e. an optimal material requires fulfillment of several criteria simultaneously – makes the screening challenging. To address this, we have developed a multi-scale approach combining high-throughput molecular simulation screening, data mining and advanced visualization, as well as process system modelling, backed up by experimental validation. We have applied our recent advances in the engineering of porous materials' morphology to develop advanced monolithic structures. These conformed, shaped monoliths can be used readily in industrial applications, bringing a valuable strategy for the development of advanced materials. This toolbox is flexible enough to be applied to multiple adsorption-based gas separation applications.
doi_str_mv	10.1039/d1sc01588e
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subjects	Adsorption Boiling points Carbon monoxide Chemistry Criteria Data mining Gas separation Industrial applications Metal-organic frameworks Morphology Multiscale analysis Physical properties Porous materials Screening
title	The development of a comprehensive toolbox based on multi-level, high-throughput screening of MOFs for CO/N2 separations
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