用于高效光催化固氮的吸盘-反应器聚氧化金属铝组装超结构

IF 6.7 1区化学 Q1 CHEMISTRY, ANALYTICAL

Analytical Chemistry Pub Date : 2024-11-12 DOI:10.1002/adma.202412924

Xiangjiao Gong, Wenkai Teng, Wei Liu, Hang Xiao, He Li, Honghui Ou, Guidong Yang

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引用次数: 0

摘要

在人工光合作用系统中设计一种将反应物捕获和转化融为一体的反应系统以实现高反应效率仍然具有挑战性。本文报告了一种离子液体（IL）-聚氧化金属（POM）超结构光催化剂（P2HPMo），通过调整离子液体的烷基链长实现超结构的各向异性。实验数据和理论模拟表明，ILs 和 POM 分别作为反应体系的 "吸盘 "和 "反应器"，捕获和转化反应物。尤其是四价磷 IL 阳离子的加入，不仅有利于 N2 的吸附，还能通过能带和电子结构的改变有效促进 N2 的活化。因此，合成的 P2HPMo 的氨合成率高达 98 µmol-gcat-1-h-1，是无牺牲剂体系中最高值之一。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

A Sucker-Reactor Polyoxometalate Assembled Superstructures for Efficient Photocatalytic Nitrogen Fixation

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A Sucker-Reactor Polyoxometalate Assembled Superstructures for Efficient Photocatalytic Nitrogen Fixation

Designing a reaction system that integrates reactant capture and transformation in an artificial photosynthesis system to achieve high reaction efficiency remains challenging. Here, an ionic liquid (IL) -polyoxometalate (POM) superstructure photocatalyst (P2HPMo) is reported, where the anisotropy of the superstructure is allowed by adjusting the alkyl chain lengths of ILs. Experimental data and theoretical simulation show that ILs and POM serve as the “sucker” and “reactor” of the reaction system to capture and transform the reactants, respectively. In particular, the addition of quaternary phosphorous IL cations is not only conducive to the adsorption of N₂ but also effectively promotes the activation of N₂ by manipulating the energy band and electronic structure. Consequently, the synthesized P2HPMo exhibits an ammonia synthesis rate of 98 µmol·g_cat⁻¹·h⁻¹, which is one of the highest values available in a sacrificial agent-free system.

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来源期刊

Analytical Chemistry 化学-分析化学

CiteScore

12.10

自引率

12.20%

发文量

1949

审稿时长

1.4 months

期刊介绍： Analytical Chemistry, a peer-reviewed research journal, focuses on disseminating new and original knowledge across all branches of analytical chemistry. Fundamental articles may explore general principles of chemical measurement science and need not directly address existing or potential analytical methodology. They can be entirely theoretical or report experimental results. Contributions may cover various phases of analytical operations, including sampling, bioanalysis, electrochemistry, mass spectrometry, microscale and nanoscale systems, environmental analysis, separations, spectroscopy, chemical reactions and selectivity, instrumentation, imaging, surface analysis, and data processing. Papers discussing known analytical methods should present a significant, original application of the method, a notable improvement, or results on an important analyte.