控制沸石孔道内环境实现炔烃/烯烃的化学选择性分离。

Control of zeolite pore interior for chemoselective alkyne/olefin separations.

机构信息

School of Materials Science and Engineering and National Institute for Advanced Materials, Nankai University, Tianjin 300350, China.

Department of Chemistry, The University of Manchester, Manchester, M13 9PL, UK.

出版信息

Science. 2020 May 29;368(6494):1002-1006. doi: 10.1126/science.aay8447.

DOI:10.1126/science.aay8447

PMID:32467390

Abstract

The efficient removal of alkyne impurities for the production of polymer-grade lower olefins remains an important and challenging goal for many industries. We report a strategy to control the pore interior of faujasite (FAU) zeolites by the confinement of isolated open nickel(II) sites in their six-membered rings. Under ambient conditions, Ni@FAU showed remarkable adsorption of alkynes and efficient separations of acetylene/ethylene, propyne/propylene, and butyne/1,3-butadiene mixtures, with unprecedented dynamic separation selectivities of 100, 92, and 83, respectively. In situ neutron diffraction and inelastic neutron scattering revealed that confined nickel(II) sites enabled chemoselective and reversible binding to acetylene through the formation of metastable [Ni(II)(CH)] complexes. Control of the chemistry of pore interiors of easily scalable zeolites has unlocked their potential in challenging industrial separations.

摘要

高效去除炔烃杂质以生产聚合物级别的低烯烃仍然是许多行业的一个重要且具有挑战性的目标。我们报告了一种通过限制孤立的开放镍(II)位在其六元环内来控制方钠石（FAU）沸石孔内环境的策略。在环境条件下，Ni@FAU 对炔烃表现出显著的吸附作用，并且能够高效分离乙炔/乙烯、丙炔/丙烯和丁炔/1,3-丁二烯混合物，分别具有前所未有的动态分离选择性 100、92 和 83。原位中子衍射和非弹性中子散射表明，受限的镍(II)位能够通过形成亚稳态[Ni(II)(CH)]配合物，对乙炔进行选择性和可逆的化学吸附。控制可扩展沸石的孔内化学性质，为其在具有挑战性的工业分离中的应用潜力提供了可能。

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控制沸石孔道内环境实现炔烃/烯烃的化学选择性分离。

Control of zeolite pore interior for chemoselective alkyne/olefin separations.

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