College of Chemistry, Chemical Engineering and Materials Science, Collaborative Innovation Center of Functionalized Probes for Chemical Imaging in Universities of Shandong , Shandong Normal University , Jinan 250014 , P. R. China.
J Org Chem. 2018 Apr 20;83(8):4545-4553. doi: 10.1021/acs.joc.8b00292. Epub 2018 Apr 2.
The introduction of a C═O, C═C, C═S, or C═N bond has emerged as an effective strategy for carbocycle synthesis. A computational mechanistic study of Rh(III)-catalyzed coupling of alkynes with enaminones, sulfoxonium ylides, or α-carbonyl-nitrones was carried out. Our results uncover the roles of dual directing groups in the three substrates and confirm that the ketone acts as the role of the directing group while the C═C, C═N, or C═S bond serves as the cyclization site. By comparing the coordination of the ketone versus the C═C, C═N, or C═S bond, as well as the chemoselectivity concerning the six- versus five-membered formation, a competition relationship is revealed within the dual directing groups. Furthermore, after the alkyne insertion, instead of the originally proposed direct reductive elimination mechanism, the ketone enolization is found to be essential prior to the reductive elimination. The following C(sp)-C(sp) reductive elimination is more favorable than the C(sp)-C(sp) formation, which can be explained by the aromaticity difference in the corresponding transition states. The substituent effect on controlling the selectivity was also discussed.
C═O、C═C、C═S 或 C═N 键的引入已成为合成碳环的有效策略。本文对铑(III)催化炔烃与烯胺酮、亚砜叶立德或α-羰基-硝酮偶联反应的计算机理进行了研究。研究结果揭示了三种底物中双导向基团的作用,并证实酮充当导向基团的作用,而 C═C、C═N 或 C═S 键作为环化位点。通过比较酮与 C═C、C═N 或 C═S 键的配位以及六元环与五元环形成的化学选择性,揭示了双导向基团之间的竞争关系。此外,在炔烃插入后,酮的烯醇化而不是最初提出的直接还原消除机制被发现是还原消除之前的关键步骤。随后的 C(sp)-C(sp)还原消除比 C(sp)-C(sp)形成更有利,这可以通过相应过渡态中芳香性的差异来解释。还讨论了取代基对控制选择性的影响。
