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Polar Organometallic Reagents


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exchange reactions of haloaromatics using various kinds of organoaluminum reagents were examined, but all attempts were unsuccessful. Then the deprotonative alumination of functionalized benzenes was investigated, a method which would be more advantageous to generate multifunctionalized aromatic aluminium compounds from the viewpoint of precursor availability. After extensive experiments using anisole and benzonitrile as model substrates, the complex lithium tri(isobutyl)(tetramethylpiperidido)aluminate i‐Bu3Al(TMP)Li 144, prepared by mixing i‐Bu3Al and LTMP in THF (Scheme 1.31) was found to be better than either Me3Al(TMP)Li 145 or Et3Al(TMP)Li 146 for achieving direct alumination under mild conditions (Scheme 1.32). The resulting aryl aluminate was treated with D2O or I2 to give the desired o‐dueterio‐ or o‐iodoanisole, respectively.

Schematic illustration of synthesis of i-Bu3Al(TMP)Li 144. Schematic illustration of ortho-alumination of a functionalized aromatic ring. Schematic illustration of model aluminate 149, obtained by sequentially treating ArC(O)Ni-Pr2 with t-BuLi and i-Bu3Al in THF. Schematic illustration of i-Bu2Al(TMP)2Li 150 has enabled the conversion of 4-halo-anisoles to triheterohalogenated anisoles 151–153. Schematic illustration of molecular structures of aluminated precursors 154 and 155 to (a) di-, and (b) triheterohalogenated anisole derivatives, respectively.

      Source: Adapted from Conway et al. [210].

Schematic illustration of the Gilman amidocuprate (TMP)2CuLi.

       1.4.5 Cuprates