Abstract
9-tert-Butylanthracene undergoes a photochemical reaction to form its strained Dewar isomer, which thermally back-reacts to reform the original molecule. When 9-tert-butylanthracene is dissolved in a polymer host, we find that both the forward and reverse isomerization rates are pressure-dependent. The forward photoreaction rate, which reflects the sum of contributions from photoperoxidation and Dewar isomerization, decreases by a factor of 1000 at high pressure (1.5 GPa). The back-reaction rate, on the other hand, increases by a factor of ∼3 at high pressure. Despite being highly strained and higher volume, the back-reaction reaction rate of the Dewar isomer is at least 100× less sensitive to pressure than that of the bi(anthracene-9,10- dimethylene) photodimer studied previously by our group. These results suggest that the high pressure sensitivity of the bi(anthracene-9,10-dimethylene) photodimer reaction is not just due to the presence of strained four-membered rings but instead relies on the unique molecular geometry of this molecule. © 2014 American Chemical Society.
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CITATION STYLE
Tong, F., Cruz, C. D., Jezowski, S. R., Zhou, X., Zhu, L., Al-Kaysi, R. O., … Bardeen, C. J. (2014). Pressure dependence of the forward and backward rates of 9-tert-butylanthracene Dewar isomerization. Journal of Physical Chemistry A, 118(28), 5349–5354. https://doi.org/10.1021/jp504771b
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