Copper-Catalyzed Hydroxylation of Aryl Halides Using Hydroxypicolinamide Ligands

IF 3.1 3区化学 Q2 CHEMISTRY, APPLIED Organic Process Research & Development Pub Date : 2024-05-30 DOI:10.1021/acs.oprd.4c00108

Daniel W. Widlicka*, Robert A. Singer, Ian Hotham, David J. Bernhardson and Samantha Grosslight,

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Abstract

Hydroxylation of haloarenes is a fundamental transformation in synthetic organic chemistry. Hydroxypicolinamide ligands enable the efficient Cu-catalyzed hydroxylation of heteroaryl halides with a wide functional group tolerance. The Cu-MPBS system, originally designed for C–N coupling, enables the Cu-catalyzed hydroxylation of aryl bromides. A related derivative, Cu-HMPS, provides exceptional reactivity and purity for hydroxylation of aryl bromides, aryl iodides, and activated aryl chlorides. Ortho-activated substrates have shown exceptionally high reactivity and selectivity for Cu-catalyzed hydroxylation. More difficult aryl chlorides, substrates that require a higher activation temperature (120 °C), may be hydroxylated by the Cu-DMPS system that has superior intrinsic ligand stability. Reaction conditions may be tuned to target substrates through ligand, solvent, and base selection. Safe and robust processing conditions have been designed utilizing aqueous KOH, K₂CO₃, or K₃PO₄ in sulfolane or sulfolane and alcohol blends.

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使用羟基吡啶酰胺配体的铜催化芳基卤化物羟化反应

卤代烯烃的羟基化是合成有机化学中的一种基本转化。羟基吡啶醯胺配体能以广泛的官能团耐受性对杂芳基卤化物进行高效的铜催化羟基化反应。最初设计用于 C-N 偶联的 Cu-MPBS 系统可实现铜催化的芳基溴羟化反应。相关衍生物 Cu-HMPS 在芳基溴化物、芳基碘化物和活化芳基氯化物的羟基化反应中具有优异的反应活性和纯度。正活化底物在 Cu 催化羟基化反应中显示出极高的反应活性和选择性。更难处理的芳基氯化物和需要更高的活化温度（120 °C）的底物，可以通过具有出色内在配体稳定性的 Cu-DMPS 系统进行羟化。可通过选择配体、溶剂和碱来调整反应条件，以适应目标底物。我们已经设计出了在磺丙烷或磺丙烷与醇的混合物中利用 KOH、K2CO3 或 K3PO4 水溶液的安全稳健的加工条件。

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来源期刊

Organic Process Research & Development 化学-应用化学

CiteScore

6.90

自引率

14.70%

发文量

251

审稿时长

2 months

期刊介绍： The journal Organic Process Research & Development serves as a communication tool between industrial chemists and chemists working in universities and research institutes. As such, it reports original work from the broad field of industrial process chemistry but also presents academic results that are relevant, or potentially relevant, to industrial applications. Process chemistry is the science that enables the safe, environmentally benign and ultimately economical manufacturing of organic compounds that are required in larger amounts to help address the needs of society. Consequently, the Journal encompasses every aspect of organic chemistry, including all aspects of catalysis, synthetic methodology development and synthetic strategy exploration, but also includes aspects from analytical and solid-state chemistry and chemical engineering, such as work-up tools，process safety, or flow-chemistry. The goal of development and optimization of chemical reactions and processes is their transfer to a larger scale; original work describing such studies and the actual implementation on scale is highly relevant to the journal. However, studies on new developments from either industry, research institutes or academia that have not yet been demonstrated on scale, but where an industrial utility can be expected and where the study has addressed important prerequisites for a scale-up and has given confidence into the reliability and practicality of the chemistry, also serve the mission of OPR&D as a communication tool between the different contributors to the field.