溶剂辅助的金属复分解反应：一种高效、多功能的合成方法，用于制备具有挑战性的铬基金属有机框架材料。

Solvent-Assisted Metal Metathesis: A Highly Efficient and Versatile Route towards Synthetically Demanding Chromium Metal-Organic Frameworks.

机构信息

Institute of Crystalline Materials, Shanxi University, Taiyuan, 030006, China.

Institute of Molecular Science, Shanxi University, Taiyuan, 030006, China.

出版信息

Angew Chem Int Ed Engl. 2017 Jun 1;56(23):6478-6482. doi: 10.1002/anie.201701217. Epub 2017 Apr 4.

DOI:10.1002/anie.201701217

PMID:28374450

Abstract

Chromium(III)-based metal-organic frameworks (Cr-MOFs) are very attractive in a wide range of investigations because of their robustness and high porosity. However, reports on Cr-MOFs are scarce owing to the difficulties in their direct synthesis. Recently developed postsynthetic routes to obtain Cr-MOFs suffered from complicated procedures and a lack of general applicability. Herein, we report a highly efficient and versatile strategy, namely solvent-assisted metal metathesis, to obtain Cr-MOFs from a variety of Fe -MOFs, including several well-known MOFs and a newly synthesized one, through judicious selection of a coordinating solvent. The versatility of this strategy was demonstrated by producing Cr-MIL-100, Cr-MIL-142A/C, Cr-PCN-333, and Cr-PCN-600 from their Fe analogues and Cr-SXU-1 from a newly synthesized MOF precursor, Fe-SXU-1, in acetone as the solvent under very mild conditions. We have thus developed a general approach for the preparation of robust Cr-MOFs, which are difficult to synthesize by direct methods.

摘要

基于铬(III)的金属有机骨架 (Cr-MOFs) 因其坚固性和高孔隙率而在广泛的研究中非常有吸引力。然而，由于直接合成的困难，关于 Cr-MOFs 的报道很少。最近开发的获得 Cr-MOFs 的后合成途径由于程序复杂且缺乏通用性而受到限制。在此，我们报告了一种高效且通用的策略，即溶剂辅助的金属复分解，通过合理选择配位溶剂，从各种 Fe-MOFs（包括几种知名的 MOF 和一种新合成的 MOF）中获得 Cr-MOFs。该策略的通用性通过在温和条件下以丙酮为溶剂，从其 Fe 类似物中制备 Cr-MIL-100、Cr-MIL-142A/C、Cr-PCN-333 和 Cr-PCN-600，以及从新合成的 MOF 前体 Fe-SXU-1 中制备 Cr-SXU-1 来证明。我们因此开发了一种通用的方法来制备难以通过直接方法合成的坚固的 Cr-MOFs。

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溶剂辅助的金属复分解反应：一种高效、多功能的合成方法，用于制备具有挑战性的铬基金属有机框架材料。

Solvent-Assisted Metal Metathesis: A Highly Efficient and Versatile Route towards Synthetically Demanding Chromium Metal-Organic Frameworks.

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