电磁铣削法与气态CO2的Barbier反应

IF 4 2区化学 Q2 CHEMISTRY, APPLIED

Advanced Synthesis & Catalysis Pub Date : 2025-09-26 DOI:10.1002/adsc.70061

Hui Wang , Fachao Yan , Yanan Hou , Long Shu , Xiaowei Li , Mingxia Zhang , Hongyou Cui , Hui Liu

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引用次数: 0

摘要

Barbier反应在有机化学中被用于构建C - X （X = C, Si， B， N等）键已有一个多世纪的历史。然而，所有报道的策略都是在有机溶剂或无溶剂条件下进行的，涉及固-液或固-固相，气相Barbier一步反应很少见。本文介绍了一种在电磁磨条件下一步气参Barbier反应合成羧酸的方法。这种方法利用环境压力下的二氧化碳气体，这对同位素标记化学具有重要的前景。用这种方法可以有效地合成多种13C标记的羧酸。这种气体参与、液体辅助的磨削转变可以加速该领域的发展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Barbier Reactions with Gaseous CO2 via Electromagnetic Milling

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Barbier Reactions with Gaseous CO2 via Electromagnetic Milling

The Barbier reaction has been utilized in the construction of CX (X = C, Si, B, N, etc.)bondsin organic chemistry for over a century. However, all reported strategies have been carried out in organic solvents or solvent‐free conditions involving solid–liquid or solid–solid phases, and gas‐phase Barbier reactions in one step are rare. In this work, a one‐step gas‐involved Barbier reaction for the synthesis of carboxylic acids under electromagnetic mill conditions is presented. This approach utilizes gas CO₂ at ambient pressure, which holds significant promise for isotope‐labeling chemistry. A variety of ¹³C‐labeled carboxylic acids is synthesized efficiently using this method. This gas‐involved, liquid‐assisted grinding transformation could accelerate the advancement of this field.

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来源期刊

Advanced Synthesis & Catalysis 化学-应用化学

CiteScore

9.40

自引率

7.40%

发文量

447

审稿时长

1.8 months

期刊介绍： Advanced Synthesis & Catalysis (ASC) is the leading primary journal in organic, organometallic, and applied chemistry. The high impact of ASC can be attributed to the unique focus of the journal, which publishes exciting new results from academic and industrial labs on efficient, practical, and environmentally friendly organic synthesis. While homogeneous, heterogeneous, organic, and enzyme catalysis are key technologies to achieve green synthesis, significant contributions to the same goal by synthesis design, reaction techniques, flow chemistry, and continuous processing, multiphase catalysis, green solvents, catalyst immobilization, and recycling, separation science, and process development are also featured in ASC. The Aims and Scope can be found in the Notice to Authors or on the first page of the table of contents in every issue.