在 UTSA-16 金属有机骨架中于干燥和湿润条件下的 CO2 捕获。

CO Capture in Dry and Wet Conditions in UTSA-16 Metal-Organic Framework.

机构信息

Department of Chemistry, NIS and INSTM reference Centres, University of Torino , Via G. Quarello 15/A, 10135 and Via P. Giuria 7, 10125 Torino, Italy.

SINTEF Materials and Chemistry , P.O. Box 124 Blindern, N0314 Oslo, Norway.

出版信息

ACS Appl Mater Interfaces. 2017 Jan 11;9(1):455-463. doi: 10.1021/acsami.6b13216. Epub 2016 Dec 22.

DOI:10.1021/acsami.6b13216

PMID:28005324

Abstract

Water is the strongest competitor to CO in the adsorption on microporous materials, affecting their performances as CO scrubbers in processes such as postcombustion carbon capture. The metal-organic framework (MOF) UTSA-16 is considered a promising material for its capacity to efficiently capture CO in large quantities, thanks to the presence of open metal sites (OMSs). It is here shown that UTSA-16 is also able to desorb fully water already at room temperature. This property is unique from all the other materials with OMSs reported so far. UTSA-16 retains indeed the 70% of its CO separation capacity after admittance of water in a test flow, created to simulate the emissions from a real postcombustion carbon-capture process. This important aspect not yet observed for any other amine-free material, associated with a high material stability-tested for 160 cycles-and a small temperature swing necessary for regeneration, places UTSA-16 in the restrict number of systems with a real technological future for CO separation.

摘要

水是在吸附于微孔材料时与 CO 最强劲的竞争对手，这会影响它们作为 CO 吸收剂在某些过程（例如后燃烧碳捕获）中的性能。金属有机骨架（MOF） UTSA-16 因其具有高效大量捕获 CO 的能力而被认为是一种很有前途的材料，这要归功于开放金属位点（OMSs）的存在。本文表明，UTSA-16 甚至能够在室温下完全解吸水。这种特性是迄今为止报道的所有具有 OMSs 的其他材料所没有的。UTSA-16 在一个测试流中允许水进入后，仍然保留了其 70%的 CO 分离能力，该测试流旨在模拟真实的后燃烧碳捕获过程中的排放。与任何其他无胺材料相比，这是一个尚未观察到的重要方面，它与经过 160 个循环测试的高材料稳定性以及再生所需的较小温度波动相关联，使 UTSA-16 成为 CO 分离领域具有实际技术前景的少数系统之一。

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在 UTSA-16 金属有机骨架中于干燥和湿润条件下的 CO2 捕获。

CO Capture in Dry and Wet Conditions in UTSA-16 Metal-Organic Framework.

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