posted on 2016-08-31, 00:00authored byMatthew
B. Baker, Renan B. Ferreira, Jonathan Tasseroul, Andrew J. Lampkins, Alexandre Al Abbas, Khalil A. Abboud, Ronald K. Castellano
Benzotrifuranone
(BTF), bearing three symmetry-equivalent
lactone rings, is unique in its ability to undergo highly selective
and sequential aminolysis reactions in one-pot to afford multifunctionalized
molecules (>80% overall yield). New insight into this behavior
is
presented through kinetics measurements (by stopped-flow IR spectroscopy),
X-ray crystal structure analysis, quantum chemical calculations, and
comparison of BTF to other benzoate esters, including
its ring expanded congener benzotripyranone (BTP). While
the structure–property investigation confirms stepwise electronic/inductive
lactone deactivation for both BTF and BTP, the unusually fast and selective aminolysis of BTF is only fully explained through synergistic ring strain effects.
Experimental signatures of the significant ring strain of BTF (∼28 kcal mol–1 based on DFT calculations
vs 17 kcal mol–1 for BTP) include its
high lactone carbonyl stretching energy (1821 cm–1 in acetonitrile vs 1777 cm–1 for BTP) and bond length alternation within its benzenoid ring. While ring
strain is relieved upon the sequential aminolysis of both BTF and BTP, it is only for the former that a ring strain
gradient is established that contributes to the stepwise aminolysis
rate differences and enhanced selectivity. The work shows how a combination
of electronic effects and ring strain can underpin the design of small
molecules capable of stepwise functionalization, of which there are
notably few examples.