通过含有可及过渡金属离子位点的多孔杂化材料进行选择性氮捕获。

Selective nitrogen capture by porous hybrid materials containing accessible transition metal ion sites.

作者信息

Yoon Ji Woong, Chang Hyunju, Lee Seung-Joon, Hwang Young Kyu, Hong Do-Young, Lee Su-Kyung, Lee Ji Sun, Jang Seunghun, Yoon Tae-Ung, Kwac Kijeong, Jung Yousung, Pillai Renjith S, Faucher Florian, Vimont Alexandre, Daturi Marco, Férey Gérard, Serre Christian, Maurin Guillaume, Bae Youn-Sang, Chang Jong-San

机构信息

Research Center for Nanocatalysts and Molecular Simulations, Korea Research Institute of Chemical Technology (KRICT), Daejeon 305-600, South Korea.

Department of Chemical and Biomolecular Engineering, Yonsei University, Seoul 120-749, South Korea.

出版信息

Nat Mater. 2017 May;16(5):526-531. doi: 10.1038/nmat4825. Epub 2016 Dec 19.

DOI:10.1038/nmat4825

PMID:27992421

Abstract

Selective dinitrogen binding to transition metal ions mainly covers two strategic domains: biological nitrogen fixation catalysed by metalloenzyme nitrogenases, and adsorptive purification of natural gas and air. Many transition metal-dinitrogen complexes have been envisaged for biomimetic nitrogen fixation to produce ammonia. Inspired by this concept, here we report mesoporous metal-organic framework materials containing accessible Cr(III) sites, able to thermodynamically capture N over CH and O. This fundamental study integrating advanced experimental and computational tools confirmed that the separation mechanism for both N/CH and N/O gas mixtures is driven by the presence of these unsaturated Cr(III) sites that allows a much stronger binding of N over the two other gases. Besides the potential breakthrough in adsorption-based technologies, this proof of concept could open new horizons to address several challenges in chemistry, including the design of heterogeneous biomimetic catalysts through nitrogen fixation.

摘要

过渡金属离子对二氮的选择性结合主要涵盖两个重要领域

金属酶固氮酶催化的生物固氮，以及天然气和空气的吸附净化。人们设想了许多过渡金属 - 二氮配合物用于仿生固氮以生产氨。受这一概念的启发，我们在此报告了含有可及Cr(III)位点的介孔金属有机骨架材料，其能够在热力学上优先于CH和O捕获N。这项整合了先进实验和计算工具的基础研究证实，N/CH和N/O气体混合物的分离机制是由这些不饱和Cr(III)位点的存在驱动的，这些位点使得N与其他两种气体相比具有更强的结合能力。除了在基于吸附的技术方面可能取得突破外，这一概念验证还可能为解决化学领域的若干挑战开辟新的前景，包括通过固氮设计多相仿生催化剂。

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通过含有可及过渡金属离子位点的多孔杂化材料进行选择性氮捕获。

Selective nitrogen capture by porous hybrid materials containing accessible transition metal ion sites.

作者信息

机构信息

出版信息

过渡金属离子对二氮的选择性结合主要涵盖两个重要领域

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