锰-氢酰胺配合物的结构、反应性和催化性能。

Structure, reactivity and catalytic properties of manganese-hydride amidate complexes.

机构信息

Center of Basic Molecular Science (CBMS), Department of Chemistry, Tsinghua University, Beijing, China.

School of Chemistry and Chemical Engineering, Chongqing Key Laboratory of Theoretical and Computational Chemistry, Chongqing University, Chongqing, China.

出版信息

Nat Chem. 2022 Nov;14(11):1233-1241. doi: 10.1038/s41557-022-01036-6. Epub 2022 Sep 12.

DOI:10.1038/s41557-022-01036-6

PMID:36097055

Abstract

The high efficiency of widely applied Noyori-type hydrogenation catalysts arises from the N-H moiety coordinated to a metal centre, which stabilizes rate-determining transition states through hydrogen-bonding interactions. It was proposed that a higher efficiency could be achieved by substituting an N-M' group (M' = alkali metals) for the N-H moiety using a large excess of metal alkoxides (M'OR); however, such a metal-hydride amidate intermediate has not yet been isolated. Here we present the synthesis, isolation and reactivity of a metal-hydride amidate complex (HMn-NLi). Kinetic studies show that the rate of hydride transfer from HMn-NLi to a ketone is 24-fold higher than that of the corresponding amino metal-hydride complex (HMn-NH). Moreover, the hydrogenation of N-alkyl-substituted aldimines was realized using HMn-NLi as the active catalyst, whereas HMn-NH is much less effective. These results highlight the superiority of M/NM' bifunctional catalysis over the classic M/NH bifunctional catalysis for hydrogenation reactions.

摘要

广泛应用的 Noyori 型氢化催化剂的高效率源于与金属中心配位的 N-H 部分，通过氢键相互作用稳定了速率决定过渡态。有人提出，通过使用过量的金属醇盐 (M'OR) 将 N-M' 基团 (M' = 碱金属) 取代 N-H 部分，可以实现更高的效率；然而，这种金属-氢化物酰胺中间体尚未被分离出来。在这里，我们提出了金属氢化物酰胺配合物 (HMn-NLi) 的合成、分离和反应性。动力学研究表明，HMn-NLi 向酮转移氢化物的速率比相应的氨基金属氢化物配合物 (HMn-NH) 高 24 倍。此外，使用 HMn-NLi 作为活性催化剂实现了 N- 烷基取代的亚胺的氢化，而 HMn-NH 的效果要差得多。这些结果突出了 M/NM' 双功能催化相对于经典 M/NH 双功能催化在氢化反应中的优越性。

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锰-氢酰胺配合物的结构、反应性和催化性能。

Structure, reactivity and catalytic properties of manganese-hydride amidate complexes.

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