Synthesis and evaluation of new mono- and binuclear salen complexes for the Cα-alkylation reaction of amino acid substrates as chiral phase transfer catalysts

IF 3.9 2区 化学 Q2 CHEMISTRY, PHYSICAL Molecular Catalysis Pub Date : 2024-10-22 DOI:10.1016/j.mcat.2024.114618
Anahit M. Hovhannisyan , Anna S. Tovmasyan , Anna F. Mkrtchyan , Karapet R. Ghazaryan , Ela V. Minasyan , Olgert L. Dallakyan , Mikayel S. Chobanyan , Hayk Zakaryan , Giovanni N. Roviello , Ashot S. Saghyan
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Abstract

In this study, we present a series of Zn(II) mono- and Cu(II) binuclear salen complexes synthesized and assessed for their effectiveness in the Cα-alkylation reaction. Through systematic experimentation, it was observed that the introduction of a methoxy group at position 3 of the phenyl group in the salicylidene ligand led to a notable enhancement in asymmetric yield, while an allyl group reduced yield. Computational DFT calculations supported the involvement of the binuclear complex in the transition state of the reaction, elucidating the underlying mechanisms governing the observed catalytic behavior. A newly synthesized binuclear complex exhibited significantly higher catalytic activity compared to its mononuclear counterpart which could potentially be explained by increased intramolecular rigidity. This comprehensive investigation not only advances our understanding of structure-activity relationships in chiral salen complexes but also provides valuable insights for the rational design and optimization of catalysts for the asymmetric Cα-alkylation reaction.

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合成和评估作为手性相转移催化剂用于氨基酸底物 Cα 烷基化反应的新型单核和双核沙林配合物
在本研究中,我们合成了一系列 Zn(II) 单核和 Cu(II) 双核水杨醛配合物,并评估了它们在 Cα 烷基化反应中的有效性。通过系统实验观察到,在水杨醛配体中苯基的第 3 位引入甲氧基会显著提高不对称产率,而烯丙基则会降低产率。计算 DFT 支持双核配合物参与反应的过渡态,阐明了观察到的催化行为的基本机制。与单核复合物相比,新合成的双核复合物表现出更高的催化活性,这可能是由于分子内刚性增加所致。这项全面的研究不仅加深了我们对手性沙林配合物结构-活性关系的理解,还为合理设计和优化用于不对称 Cα 烷基化反应的催化剂提供了宝贵的见解。
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来源期刊
Molecular Catalysis
Molecular Catalysis Chemical Engineering-Process Chemistry and Technology
CiteScore
6.90
自引率
10.90%
发文量
700
审稿时长
40 days
期刊介绍: Molecular Catalysis publishes full papers that are original, rigorous, and scholarly contributions examining the molecular and atomic aspects of catalytic activation and reaction mechanisms. The fields covered are: Heterogeneous catalysis including immobilized molecular catalysts Homogeneous catalysis including organocatalysis, organometallic catalysis and biocatalysis Photo- and electrochemistry Theoretical aspects of catalysis analyzed by computational methods
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