Experimental and Theoretical Investigation of Interfacial Engineering in Fe₂O₃/NiFe₂O₄ Heterostructures toward the Cycloaddition of CO₂ with Styrene Oxide.

IF 4.3 2区化学 Q1 CHEMISTRY, INORGANIC & NUCLEAR Inorganic Chemistry Pub Date : 2024-07-01 DOI:10.1021/acs.inorgchem.4c01696

Jiangyong Liu, Bin Zhang, Panming Jian, Jie Shi

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Abstract

The chemical fixation of CO₂ into epoxides for the synthesis of cyclic carbonates is an appealing solution to both reduce global CO₂ emission and produce fine chemicals, but it is still a prime challenge to develop a low-cost, earth-abundant, yet efficient solid catalyst. Herein, Fe₂O₃/NiFe₂O₄ heterostructures are facilely constructed for the highly efficient cycloaddition of CO₂ with styrene oxide (SO) to produce styrene carbonate (SC). Both experimental findings and density functional theory (DFT) calculations substantiate the prominent electron transfer and charge redistribution within the heterointerfaces between the biphasic components, which induce a unique interfacial microenvironment that can facilitate the adsorption and activation of SO. This endows the biphasic catalyst with a substantially higher reactivity than the individual components. This study sheds new insights into the establishment of heterostructured catalysts consisting of transitional metal oxides for the high-efficiency production of SC from the cycloaddition of CO₂ with SO.

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对氧化铁/氧化镍异质结构中的界面工程进行实验和理论研究，以实现二氧化碳与氧化苯乙烯的环加成。

将二氧化碳化学固定为环氧化物以合成环状碳酸盐是一种既能减少全球二氧化碳排放又能生产精细化学品的极具吸引力的解决方案，但开发一种低成本、富含地球资源且高效的固体催化剂仍是一项重大挑战。在本文中，Fe2O3/NiFe2O4 异质结构很容易构建，用于 CO2 与氧化苯乙烯 (SO) 的高效环加成反应，生成碳酸苯乙烯 (SC)。实验结果和密度泛函理论（DFT）计算均证实，双相成分之间的异质界面内存在显著的电子转移和电荷再分布，从而形成独特的界面微环境，促进 SO 的吸附和活化。这使得双相催化剂的反应活性大大高于单个组分。这项研究为建立由过渡金属氧化物组成的异质结构催化剂，通过 CO2 与 SO 的环加成反应高效生产 SC 提供了新的视角。

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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来源期刊

Inorganic Chemistry 化学-无机化学与核化学

CiteScore

7.60

自引率

13.00%

发文量

1960

审稿时长

1.9 months

期刊介绍： Inorganic Chemistry publishes fundamental studies in all phases of inorganic chemistry. Coverage includes experimental and theoretical reports on quantitative studies of structure and thermodynamics, kinetics, mechanisms of inorganic reactions, bioinorganic chemistry, and relevant aspects of organometallic chemistry, solid-state phenomena, and chemical bonding theory. Emphasis is placed on the synthesis, structure, thermodynamics, reactivity, spectroscopy, and bonding properties of significant new and known compounds.