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Methodologies in Amine Synthesis. Группа авторовЧитать онлайн книгу.

Methodologies in Amine Synthesis - Группа авторов


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Ayer, S.K. and Roizen, J.L. (2019). The Journal of Organic Chemistry 84: 3508–3523.

      59 59 Torres‐Ochoa, R.O., Leclair, A., Wang, Q., and Zhu, J. (2019). Chemistry ‐ A European Journal 25: 9477–9484.

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       Binbin Huang1, Yating Zhao2, and Wujiong Xia1

       1Harbin Institute of Technology, State Key Lab of Urban Water Resource and Environment, School of Science, Shenzhen, 518055, China

       2Quzhou University, College of Chemical and Material Engineering, Quzhou, China, 324000

      As ubiquitous fundamental linkages, C—N bonds prevalently exist in various value‐added compounds such as natural products, pharmaceutical agents, functional materials, synthetic intermediates, and coordinating ligands. Thus, developing efficient methodologies for the construction of C—N bonds has always been a hot research goal in synthetic chemistry [1]. Among the existing approaches toward C—N bonds, cross‐dehydrohalogenative couplings of C—H/N—X (X = halide or pseudo‐halide) bonds or C—X/N—H bonds are generally well established, highly efficient, and consequently widely used, including the classical Buchwald–Hartwig amination and Ullman amination. However, from the perspective of green chemistry, these methods are not the ideal choices because the requirement for prefunctionalization of the coupling substrates considerably lowers their atom and step economy.

      During the past few decades, cross‐dehydrogenative coupling (CDC) has emerged as an attractive technique, in which preinstallation of a reactive group in either of the coupling precursors is avoided, thus featuring higher atom and step economy in synthetic chemistry. Accordingly, CDC amination, which furnishes C—N bonds directly from unfunctionalized C—H bonds and N—H bonds, is acknowledged as one of the most straightforward approaches for C—N bond construction. In this field, transition‐metal‐mediated CDC aminations have been more extensively investigated, as summarized in the reviews by Patureau and coworker [2] and Chang and coworker [3]. Generally, these protocols depend on the interaction of the metal catalysts with the preinstalled directing groups on the substrates to facilitate the following amination. However, both the installation and the removal of such groups are tedious work that makes these strategies practically compromised. While, in other C–H aminations without chelation, the substrate scopes of carbon moieties are mostly limited to certain acidic C—H bonds that are more prone to activation. Nevertheless, these limitations have been overcome, wherein the direct conversion of unfunctionalized N—H and C—H bonds into C—N bonds have been achieved via reactive metal‐nitrenoid species [4]. Apart from metal chemistry, metal‐free direct oxidative C–H aminations have also been realized by the groups of Antonchick, Deboef, Chang, etc., via the mediation of hypervalent iodine reagents [5].

Chemical reaction depicts C-N bond formation applying N-H bonds via photo/electrochemical methods.

      3.2.1 Radical Addition to C—C Double/Triple Bonds

      3.2.1.1 Amidyl Radical Addition

      In the successful examples directly employing N—H bonds as the radical precursors, the N—H bonds of most aminating reagents possess relatively low pKa values to facilitate their effective oxidation. Besides, electron‐deficient functional groups such as acyl groups and sulfonyl groups (–Ts) adjacent to the N‐atom can also significantly stabilize the generated N‐radical species. Thus, amidyl or sulfonamidyl radicals often appear as the key intermediates in the N‐radical‐based C—N bond formation.

      During the past few years, proton‐coupled electron transfer (PCET) strategy has been adopted in synthetic chemistry by Knowles' group, particularly for the homolytic activation of strong N—H bonds to form N‐radical species that could further engage in various C—N bonds constructing transformations. Different from the straightforward hydrogen atom transfer (HAT) process, in a typical PCET‐enabled amination, the most crucial step is the formation of a discrete hydrogen bond complex between the N—H bond of the substrate and the catalytic Brønsted base to modulate the redox potential, which enables the following concerted exchange step of an electron and a proton to access the N‐radical species.


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