Intermediate-sized molecular sieving of styrene from larger and smaller analogues

Molecular sieving can lead to ultrahigh selectivity and low regeneration energy because it completely excludes all larger molecules via a size restriction mechanism. However, it allows adsorption of all molecules smaller than the pore aperture and so separations of complicated mixtures can be hinder...

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Veröffentlicht in:	Nature materials 2019-09, Vol.18 (9), p.994-998
Hauptverfasser:	Zhou, Dong-Dong, Chen, Pin, Wang, Chao, Wang, Sha-Sha, Du, Yunfei, Yan, Hui, Ye, Zi-Ming, He, Chun-Ting, Huang, Rui-Kang, Mo, Zong-Wen, Huang, Ning-Yu, Zhang, Jie-Peng
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Sprache:	eng
Schlagworte:	119/118 639/301/299/1013 639/638/298/921 Adsorption Apertures Benzene Biomaterials Chemistry and Materials Science Computer simulation Condensed Matter Physics Ethylbenzene Flexibility Hydrocarbons Hydrophobicity Materials Science Metal-organic frameworks Nanotechnology Optical and Electronic Materials Organic chemistry Regeneration Selectivity Styrene Styrenes Toluene
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container_title	Nature materials
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creator	Zhou, Dong-Dong Chen, Pin Wang, Chao Wang, Sha-Sha Du, Yunfei Yan, Hui Ye, Zi-Ming He, Chun-Ting Huang, Rui-Kang Mo, Zong-Wen Huang, Ning-Yu Zhang, Jie-Peng
description	Molecular sieving can lead to ultrahigh selectivity and low regeneration energy because it completely excludes all larger molecules via a size restriction mechanism. However, it allows adsorption of all molecules smaller than the pore aperture and so separations of complicated mixtures can be hindered. Here, we report an intermediate-sized molecular sieving (iSMS) effect in a metal–organic framework (MAF-41) designed with restricted flexibility, which also exhibits superhydrophobicity and ultrahigh thermal/chemical stabilities. Single-component isotherms and computational simulations show adsorption of styrene but complete exclusion of the larger analogue ethylbenzene (because it exceeds the maximal aperture size) and smaller toluene/benzene molecules that have insufficient adsorption energy to open the cavity. Mixture adsorption experiments show a high styrene selectivity of 1,250 for an ethylbenzene/styrene mixture and 3,300 for an ethylbenzene/styrene/toluene/benzene mixture (orders of magnitude higher than previous reports). This produces styrene with a purity of 99.9%+ in a single adsorption–desorption cycle. Controlling/restricting flexibility is the key for iSMS and can be a promising strategy for discovering other exceptional properties. Molecular sieving separates larger from smaller molecules, but all molecules smaller than the pore adsorb, hindering selectivity. Here, a MOF is reported with both molecular sieving and gate-opening, separating intermediate-sized molecules from larger and smaller analogues.
doi_str_mv	10.1038/s41563-019-0427-z
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Mixture adsorption experiments show a high styrene selectivity of 1,250 for an ethylbenzene/styrene mixture and 3,300 for an ethylbenzene/styrene/toluene/benzene mixture (orders of magnitude higher than previous reports). This produces styrene with a purity of 99.9%+ in a single adsorption–desorption cycle. Controlling/restricting flexibility is the key for iSMS and can be a promising strategy for discovering other exceptional properties. Molecular sieving separates larger from smaller molecules, but all molecules smaller than the pore adsorb, hindering selectivity. 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subjects	119/118 639/301/299/1013 639/638/298/921 Adsorption Apertures Benzene Biomaterials Chemistry and Materials Science Computer simulation Condensed Matter Physics Ethylbenzene Flexibility Hydrocarbons Hydrophobicity Materials Science Metal-organic frameworks Nanotechnology Optical and Electronic Materials Organic chemistry Regeneration Selectivity Styrene Styrenes Toluene
title	Intermediate-sized molecular sieving of styrene from larger and smaller analogues
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