Liumei Li , Zicheng Wang , Lina Zhao, Hongbo Liu, Yuxin Li
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引用次数: 0
Abstract
Employing photocatalysis to diminish CO2 concentrations when exposed to visible spectrum illumination, converting it into energy materials and chemical products, is an effective method to achieve carbon cycling. Among the many catalysts, lanthanide-based metals, with gradually filling 4f orbitals that give them unique electronic structures, have garnered significant focus on the domain of decreasing CO2 via photocatalytic methods. Lanthanide metals exhibit a 4f orbital shielding effect, meaning that the f-electrons neither engage in atomic interactions or have substantial orbital convergence with ligands. This minimizes the influence of the external environment on the outer electrons, allowing lanthanide-based catalysts to remain stable. This distinctive property also helps increase surface defects in the catalyst, forming charge bridges or heterojunctions that promote rapid electron transfer and inhibit the reunion of electrons and vacancies. To fully harness the photogenerated electrons in photocatalytic CO2 reduction. However, as a result of the Laporte selection rule, the kinetic functionality of lanthanide metals is somewhat restricted and requires sensitization by other components. Therefore, understanding and designing the regulatory mechanisms of lanthanide metals is a notable area that warrants further investigation and analysis. Unfortunately, comprehensive reports in this field remain quite limited. Against this backdrop, this paper primarily summarizes the latest developments in lanthanide-based catalysts for CO2 reduction. It concentrates on the regulatory mechanisms of different lanthanide elements in the CO2 reduction method and elucidates the reduction mechanisms. Various photoelectrochemical tests, such as Transient Absorption Spectroscopy (TAS) and Synchrotron X-ray Diffraction (SXRD), have also confirmed that lanthanide catalysts can boost the efficiency of CO2 mitigation. Lastly, the challenges facing lanthanide catalysts within the sphere of photocatalytic CO2 reduction are discussed, and recommendations for future research directions are provided.
利用光催化技术降低二氧化碳在可见光谱照射下的浓度,并将其转化为能源材料和化学产品,是实现碳循环的有效方法。在众多催化剂中,镧系元素金属具有逐渐填充的 4f 轨道,使其具有独特的电子结构,因此在通过光催化方法减少二氧化碳的领域备受关注。镧系金属具有 4f 轨道屏蔽效应,这意味着 f 电子既不参与原子相互作用,也不会与配体产生大量轨道会聚。这最大程度地减少了外部环境对外层电子的影响,使镧系催化剂保持稳定。这种独特的性质还有助于增加催化剂的表面缺陷,形成电荷桥或异质结,从而促进电子的快速转移,抑制电子和空位的重合。在光催化还原二氧化碳的过程中,要充分利用光生电子。然而,由于拉波特选择规则,镧系金属的动力学功能受到一定限制,需要其他成分的敏化。因此,了解和设计镧系金属的调节机制是一个值得进一步研究和分析的重要领域。遗憾的是,这一领域的综合报告仍然相当有限。在此背景下,本文主要总结了用于还原二氧化碳的镧系催化剂的最新发展。它集中研究了不同镧系元素在二氧化碳还原法中的调节机制,并阐明了还原机制。各种光电化学测试,如瞬态吸收光谱(TAS)和同步辐射 X 射线衍射(SXRD),也证实了镧系催化剂可以提高二氧化碳减排的效率。最后,讨论了镧系催化剂在光催化二氧化碳还原领域所面临的挑战,并对未来的研究方向提出了建议。
期刊介绍:
Coordination Chemistry Reviews offers rapid publication of review articles on current and significant topics in coordination chemistry, encompassing organometallic, supramolecular, theoretical, and bioinorganic chemistry. It also covers catalysis, materials chemistry, and metal-organic frameworks from a coordination chemistry perspective. Reviews summarize recent developments or discuss specific techniques, welcoming contributions from both established and emerging researchers.
The journal releases special issues on timely subjects, including those featuring contributions from specific regions or conferences. Occasional full-length book articles are also featured. Additionally, special volumes cover annual reviews of main group chemistry, transition metal group chemistry, and organometallic chemistry. These comprehensive reviews are vital resources for those engaged in coordination chemistry, further establishing Coordination Chemistry Reviews as a hub for insightful surveys in inorganic and physical inorganic chemistry.