Polar Organometallic Reagents. Группа авторов

Polar Organometallic Reagents - Группа авторов


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1.8 The use of (DipNacnac)MgTMP 27 in pyrazine deprotometalation.

       1.2.2 Bimetallic Bases

      1.2.2.1 Group 1/1 Reagents

      An alternative approach to directed aromatic metalation has focused not upon replacing the alkyllithium base but on activating it. Two methods by which to achieve this were developed some time ago. The first was centered on TMEDA‐activation (TMEDA = N,N,N′,N′‐tetramethylethylenediamine) and the second involved the use of tert‐butoxide‐complexed alkyllithium reagents in the form of LICKOR superbases. The former route was employed to achieve site‐selective deprotonation with different selectivity to that achieved using the alkyllithium alone. Meanwhile, whereas unimetallic superbases are known [41], 1966–1967 saw the introduction by Lochmann [42] and Schlosser [43] of heterobimetallic (Li–Na/K) superbases. Subsequently extended to incorporate a range of alkyllithium adducts of potassium alkoxides [44], the most widely known example deploys traditional organolithium reagents in tandem with KOt‐Bu. Such heterobimetallic systems have shown enormous reactivity toward deprotonative metalation [45, 46]. As such, they enable the smooth deprotometalation of low acidity hydrocarbons [47] and weakly activated or nonactivated benzene derivatives [48] with, in some cases, unique regioselectivity [49] and also the facility for multideprotonation [50]. Whilst the synthetic importance of heterobimetallic superbases was quickly established, the characterization of such air‐sensitive materials lagged behind.

      Sources: Adapted from Mackenzie et al. [54]; Kennedy et al. [55].

Schematic illustration of reactivity of metal alkoxides towards toluene in C5D5N. Schematic illustration of molecular structure of4 344.

      Source: Adapted from Harder and Streitwieser [59].


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