Litcius/Paper detail

CO<sub>2</sub> Chemical Fixation into Value-Added Heterocycles Catalyzed by Non-Noble-Metal Metal-Organic Frameworks

Fang‐Yu Ren, Bin Zhao

2025Accounts of Chemical Research20 citationsDOI

Abstract

Conspectus The conversion of CO 2 into high-value-added chemicals represents an effective strategy for CO 2 utilization. However, due to the inherent thermodynamic stability of CO 2, its conversion primarily relies on harsh conditions, such as high temperatures and pressures, along with the involvement of noble-metal catalysts. The effective transformation of CO 2 under mild conditions remains a significant challenge. Therefore, the development of efficient catalysts is of critical importance. Metal–organic frameworks (MOFs) are a class of porous crystalline materials formed by the self-assembly of metal ions with multidentate organic ligands through coordination bonds. Its precise and customizable structure, combined with high surface area and the ease of functional modification, makes it an ideal platform for catalytic applications. These advantages facilitate the design of catalysts with high activity, selectivity, and stability through rational structural modulation, significantly enhancing CO 2 conversion into value-added products under mild conditions. Moreover, this enables a deep understanding of the relationship between catalyst structure and performance. Therefore, summarizing research in this field and providing in-depth insight into the application of MOF-based catalysts for CO 2 conversion is crucial for advancing future developments. In this Account, we will summarize and discuss recent advances on the structural design of non-noble metal MOFs and the mechanics in the catalytic conversion of CO 2, especially emphasizing how to enhance the catalytic activity and selectivity by modulating Lewis acid and/or base sites. This Account begins by outlining the challenges associated with CO 2 conversion. Subsequently, illustrating why MOFs are promising catalysts for CO 2 utilization. Next, we present several specific strategies for constructing highly efficient MOF-based catalysts utilized in CO 2 conversion: (1) To overcome the stability challenges associated with MOFs in CO 2 conversion, we designed and synthesized a series of cluster-based MOFs. The high connectivity of the metal clusters imparts exceptional structural stability. (2) We highlighted a new strategy involving multiple Lewis acid sites to synergistically catalyze the highly efficient conversion of CO 2 under mild conditions without the need for noble metals. (3) To obtain selective conversion of different reactions, we simultaneously introduced both Lewis acid and Lewis base active sites into the MOF structure. This approach significantly enhances catalytic efficiency while enabling a “switch-on/off” effect for different CO 2 reactions. (4) Through the nanoconfinement effect, we achieved substrate size selectivity and reaction pathway modulation, significantly improving the efficiency of multicomponent CO 2 reactions and reducing the formation of byproducts. Furthermore, we provided a comprehensive overview of the progress, summarized the advantages and limitations of current explorations, and discussed the potential outlook for future development. We believe that this Account will provide valuable insights into the emerging field of CO 2 chemical fixation catalyzed by non-noble-metal MOFs.

Topics & Concepts

CatalysisRational designChemistryNanotechnologyChemical stabilityCombinatorial chemistrySelectivityDenticityLewis acids and basesBiochemical engineeringMetalHeterogeneous catalysisPorosityCatalytic efficiencyMaterials scienceDissociation (chemistry)Base metalMetal-organic frameworkChemical processStabilizer (aeronautics)Carbon fixationCarbon dioxide utilization in catalysisMetal-Organic Frameworks: Synthesis and ApplicationsCO2 Reduction Techniques and Catalysts