Controlling Catalyst Speciation to Achieve Room Temperature Pd‐Catalyzed Aminations with Aryl and Heteroaryl Chlorides

IF 4.4 2区化学 Q2 CHEMISTRY, APPLIED Advanced Synthesis & Catalysis Pub Date : 2025-01-16 DOI:10.1002/adsc.202401337

Mariur Rodriguez Moreno, Mary L. Setelin, Joshua D. Hansen, James L. Corey, Kirt L. Noble, Lillian R. Stillwell, Emily Angell, Olivia A. Stubbs, Jugal Kumawat, Carlos Santiago Muñoz Gomez, Stacey J. Smith, Daniel H. Ess, David Michaelis

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Abstract

The amination of aryl halides with palladium catalysts (Buchwald‐Hartwig amination) is a widely used transformation in synthetic and drug discovery chemistry. In this report, we demonstrate that a monometallic 2‐phosphinoimidazole Pd catalyst exhibits comparable or enhanced reactivity when compared to all ligands screened for room temperature amination of aryl chlorides with secondary amines. The di‐tert‐butylphosphine derivative showed extremely high reactivity while the di‐isopropyl variant led to almost complete loss of catalytic activity. Computational and experimental mechanistic and kinetic studies indicate that a monometallic Pd structure rather than a bimetallic Pd structure is key to fast catalysis. The di‐tert‐butylphosphine ligand has fast catalysis because it thermodynamically disfavors the formation of a much less active bimetallic Pd complex. A wide substrate scope is demonstrated for the arylation of secondary amines with aryl chlorides using our new catalyst system.

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控制催化剂形态实现室温钯催化芳基和杂芳基氯化物胺化

钯催化芳基卤化物胺化反应（Buchwald - Hartwig胺化反应）是一种广泛应用于合成和药物发现化学的转化反应。在这篇报告中，我们证明了一种单金属2‐磷酰咪唑钯催化剂与所有筛选的用于芳酰氯与仲胺室温胺化的配体相比，具有相当或增强的反应活性。二叔丁基膦衍生物表现出极高的反应活性，而二异丙基衍生物几乎完全丧失了催化活性。计算和实验的机理和动力学研究表明，单金属钯结构而不是双金属钯结构是快速催化的关键。二叔丁基膦配体具有快速的催化作用，因为它在热力学上不利于形成活性低得多的双金属钯配合物。广泛的底物范围证明了仲胺与芳酰氯的芳化使用我们的新催化剂系统。

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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.