The Role of Reticular Chemistry in the Design of CO Reduction Catalysts

Overview

Journal Nat Mater

Date 2018 Feb 28

PMID 29483634

Citations 50

Authors

Christian S Diercks

Yuzhong Liu

Kyle E Cordova

Omar M Yaghi

Affiliations

Soon will be listed here.

Abstract

The problem with current state-of-the-art catalysts for CO photo- or electroreduction is rooted in the notion that no single system can independently control, and thus optimize, the interplay between activity, selectivity and efficiency. At its core, reticular chemistry is recognized for its ability to control, with atomic precision, the chemical and structural features (activity and selectivity) as well as the output optoelectronic properties (efficiency) of porous, crystalline materials. The molecular building blocks that are in a reticular chemist's toolbox are chosen in such a way that the structures are rationally designed, framework chemistry is performed to integrate catalytically active components, and the manner in which these building blocks are connected endows the material with the desired optoelectronic properties. The fact that these aspects can be fine-tuned independently lends credence to the prospect of reticular chemistry contributing to the design of next-generation CO reduction catalysts.

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