Emerging opportunities with metal-organic framework electrosynthetic platforms

IF 6.1 Q2 CHEMISTRY, PHYSICAL

Chemical physics reviews Pub Date : 2022-06-01 DOI:10.1063/5.0090147

Kiran Kuruvinashetti, Junnan Li, Yuxuan Zhang, Hossein Bemana, Morgan McKee, N. Kornienko

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引用次数: 1

Abstract

The development of electrochemical technologies is becoming increasingly important due to their growing part in renewable energy conversion and storage. Within this context, metal organic frameworks (MOFs) are finding an important role as electrocatalysts. Specifically, their molecularly defined structure across several lengths scales endows them functionality not accessible with conventional heterogeneous catalysts. To this end, this perspective will focus on the unique features within MOFs and their analogs that enable them to carry out electrocatalytic reactions in unique ways to synthesize fuels and value-added chemicals from abundant building blocks like CO2 and N2. We start with a brief overview of the initial advent of MOF electrocatalysts prior to moving to overview the forefront of the field of MOF-based electrosynthesis. The main discussion focuses on three principal directions in MOF-based electrosynthesis: multifunctional active sites, electronic modulation, and catalytic microenvironments. To conclude, we identify several challenges in the next stage of MOF electrocatalyst development and offer several key directions to take as the field matures.

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金属有机框架电合成平台的新兴机遇

由于电化学技术在可再生能源转换和储存中的作用越来越大，电化学技术的发展变得越来越重要。在这种背景下，金属有机框架（MOFs）作为电催化剂发挥着重要作用。具体而言，它们在几个长度尺度上的分子定义结构赋予了它们传统多相催化剂无法获得的功能。为此，这一观点将侧重于MOFs及其类似物的独特特征，这些特征使它们能够以独特的方式进行电催化反应，从丰富的构建块（如CO2和N2）中合成燃料和增值化学品。我们首先简要概述了MOF电催化剂的最初出现，然后概述了基于MOF的电合成领域的前沿。主要讨论基于MOF的电合成的三个主要方向：多功能活性位点、电子调制和催化微环境。总之，我们确定了MOF电催化剂开发下一阶段的几个挑战，并随着该领域的成熟提供了几个关键方向。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Chemical physics reviews

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