posted on 2018-11-07, 21:22authored byTae Ann Kim, Maxwell J. Robb, Jeffrey S. Moore, Scott R. White, Nancy R. Sottos
We
investigate the effect of pulling point location on the mechanochemical
activation of two isomers of spiropyran in cross-linked polymeric
materials through computational calculations and in situ fluorescence
measurements. The threshold stress and strain required to activate
the spiropyran mechanophores under tensile load are characterized.
For both spiropyran isomers, applied stress favors the activated merocyanine
states; however, despite differences in mechanochemical behavior predicted
by quantum chemical calculations and previous single molecule experiments,
both spiropyran isomers exhibit similar mechanochemical reactivity
in bulk polymeric materials. The kinetics of the spiropyran–merocyanine
transition under different tensile stresses are also examined. Overall,
we find that varying the pulling geometry on the spiropyran mechanophore
has only a minimal effect on the mechanical activation in bulk polymeric
materials due to the complex nature of the macroscopic system.