High level ab initio and density functional theory computations
have been used to assess the aromaticity
and antiaromaticity of the cations and anions derived from
cyclopentadiene (C5H6), indene
(C9H8), and fluorene
(C13H10). On the basis of the IGLO
calculated magnetic susceptibility exaltations (Λtot) and
the GIAO computed
nucleus independent chemical shifts (NICS), the cyclopentadienyl
(C5H5
-), indenyl
(C9H7
-), and fluorenyl
(C13H9
-)
anions are, as expected, highly aromatic as compared with benzene,
naphthalene, and anthracene. The aromaticity
or antiaromaticity of the individual rings has been characterized by
using the nucleus independent chemical shifts
(NICS) based on the magnetic shieldings calculated at the ring centers.
In addition to NICS, the computed Li+
NMR chemical shifts, another useful aromaticity probe, provide data for
the individual rings. The singlet
cyclopentadienyl (C5H5
+) and
indenyl (C9H7
+) cations are as
antiaromatic as cyclobutadiene and benzocyclobutadiene.
However, the fluorenyl cation
(C13H9
+) is non-aromatic by the
calculated magnetic susceptibility exaltation, due to
the essentially complete compensation of the diamagnetic and the
paramagnetic character. Such compensation effects
are shown directly by the geometric, energetic, and magnetic
differences between the delocalized and localized
systems computed by means of the orbital deletion procedure (ODP), in
which the critical carbocation p orbital is
“deactivated”. This shows the delocalization energies of
aromatic cations to be much larger than those of the
antiaromatic cations, and the former are stabilized and the latter are
destabilized relative to non-aromatic systems.
In contrast to the cyclopentadienyl cation, which has a triplet
ground state, the triplet indenyl and fluorenyl cations
are higher in energy than their singlet states by 9.2. and 14.9
kcal/mol, respectively.
A very effective strategy has been devised for the synthesis of 3-substituted pyrroles based on the use of the triisopropylsilyl (TIPS) moiety as a sterically demanding nitrogen substituent to obstruct the attack of electrophilic reagents at the a positions. 1 -(Triisopropylsilyl) pyrrole (1) undergoes highly preferential kinetic electrophilic substitution at the ß position with a variety of electrophiles (Br+, I+, N02+, RCO+, etc.) and fluoride ion induced desilylation of the products provides the corresponding 3-substituted pyrroles in good overall yields. Competitive trifluoroacetylation experiments demonstrate that substitution of TIPS-pyrrole at the a positions is decelerated by a factor of >104, vs pyrrole at the same sites, without affecting reactivity at the ß positions. l-(Triisopropylsilyl)-3-bromopyrrole ( 2) is readily converted into the 3-lithio compound 44 by bromine-lithium interchange with alkyllithium reagents. This previously unavailable, formal equivalent of 3-lithiopyrrole is itself an excellent source of a wide range of /3-substituted pyrroles, many of which would not be directly preparable from 1.TIPS-pyrrole can be 3,4-dihalogenated and these compounds undergo sequential halogen-metal interchange trapping reactions. This process is exemplified by an efficient, three-step synthesis of the antibiotic verrucarin E (63) from the dibromo compound 5. * Contribution no. 792.
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