posted on 2018-08-22, 00:00authored byQuan Li, Hai Qian, Baihao Shao, Russell P. Hughes, Ivan Aprahamian
Strain
has been used as a tool to modulate the reactivity (e.g.,
mechanochemistry) and thermal isomerization kinetics of photochromic
compounds. Macrocyclization is used to build-up strain in such systems,
and in general the reactivity and rates increase with the decrease
in macrocycle size. To ascertain the effect of strain on recently
reported bistable hydrazone photoswitches, we incorporated them into
macrocycles having varying aliphatic linker lengths (C3–C7), and studied their switching behavior, and
effect of macrocycle size on the thermal isomerization rate. Surprisingly,
while the systems with C3–C5 linkers
behave as expected (i.e., the rate is faster with smaller linkers),
the isomerization rate in the systems with larger aliphatic linkers
(C6–C8) is enhanced up to 4 orders
of magnitude. NMR spectroscopy, X-ray crystallography and DFT calculations
were used to elucidate this unexpected behavior, which on the basis
of our analyses results from the buildup of Pitzer (torsional), Prelog
(transannular) and Baeyer (large angle) strain in the longer linkers.