Contractive annulation was recently developed in our group as a new strategy for the synthesis of small,
strained cyclophanes. The crux of the strategy is that a bridge atom is used in the π-extension of an
aromatic ring in an existing cyclophane. As such, the growth of the aromatic system is necessarily
accompanied by the contraction of the bridge. This brings with it an increase in molecular strain. A key
feature of contractive annulation is that aromatic stabilization energy is used to counterbalance the
increase in strain energy.
Contractive annulation was first used successfully in the synthesis of [2.1]naphthalenophane 2 from
[2.2]paracyclophane (1).1 It was subsequently demonstrated that it could be applied in a two-directional
fashion in the synthesis of [1.1]naphthalenophane 3.2 Opportunities abound for the further development
of the contractive annulation strategy, using not only [2.2]paracyclophane (1) as a starting material, but
also other cyclophanes such as the [n](2,7)pyrenophanes, e.g. [8](2,7)pyrenophane (4). Single
contractive annulation of 4 would lead to benzopyrenophane 5 and double contractive annulation would
afford dibenzopyrenophanes 6 and 7. Progress toward the achievement of these objectives will be
presented.