Polar Organometallic Reagents. Группа авторов. Читать онлайн. Newlib. NEWLIB.NET

Автор: Группа авторов
Издательство: John Wiley & Sons Limited
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Жанр произведения: Химия
Год издания: 0
isbn: 9781119448846
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in in situ cuprate syntheses a Li salt by‐product is often formed and is rarely separated prior to application of the cuprate. Whilst the influence upon and/or inclusion of LiX (X = an inorganic anion, often a halide) in cuprate structures has been subject to several investigations (most recently by in‐depth NMR spectroscopy), solid‐state evidence for association remains rare (X = CN constitutes a special class of cuprate, which is discussed separately). However, the reaction of ortho diamine‐chelated aryllithium reagents with CuBr has given cuprates of formula Ar2Cu(Br)Li2 (Ar = C6H4{CH2N(Me)CH2CH2NMe2}‐2 112 and 1‐C10H6{CH2N(Me)CH2CH2NMe2}‐2 113, Figure 1.15) [148]. Interestingly, it was noted that the benzylic nitrogen centres became stereogenic upon coordination to Li, though only R,R and S,S pairs were observed in the solid‐state, implying selectivity during assembly.

Schematic illustration of molecular structure of {C6H4(CH2N(Me)CH2CH2NMe2)-2}2Cu(Br)Li2 112.

      Source: Adapted from Kronenburg et al. [148].

Schematic illustration of molecular structures of (a) polymeric (DMBA)2Cu(CN)Li2(THF)4 114, (b)[CN{Li(THF)(PMDETA)}2] 115 and (c) a cuprophilic aggregate of t-BuCu(CN)Li2(Et2O)2 116.

      Sources: Adapted from Kronenburg et al. [162]; Boche et al. [163].

      Several explanations have been posited for the apparently higher reactivity of Lipshutz cuprates, though the idea has also been contested [164]. Indeed, it has been suggested that the differing solubility of organic groups may be a contributory factor to observed variations in reactivity. For example, NMR spectroscopy uncovered the possibility that unreactive Cu‐rich cuprates may form in the presence of LiI when the organic groups were solubilizing [165], whereas lower‐order cyanocuprates (which did not interfere with unconsumed reactant) were the preferred sink for organocopper by‐product in the presence of cyanide. Differences in reactivity could then be understood in terms of the ability of the organocopper by‐product to sequester otherwise reactive cuprate. However, while these ideas have been considered in the context of applied conjugate addition, they have yet to be applied in detail to directed deprotonation or to copper‐halogen exchange reactions.

       1.3.4 Solid‐phase Synthesis