A nonconventional,
water-mediated catalytic mechanism was proposed
to explain the effects of residual water on the reactivity and regioselectivity
of tris(pentafluorophenyl)borane catalyst in the ring-opening reaction
of 1,2-epoxyoctane by 2-propanol. This nonconventional mechanism was
proposed to operate in parallel with conventional Lewis acid-catalyzed
ring-opening. Microkinetic modeling was conducted to validate the
proposed reaction mechanism, with all kinetic and thermodynamic parameters
derived from density functional theory (DFT) calculations. Experimental
data at a variety of temperatures and water contents were captured
by the model after adjustments within reasonable limits set by experimental
benchmarking and accuracy of theory of a small subset of parameters.
In addition, the microkinetic model was able to generate accurate
predictions at reaction conditions that were not used for parameter
estimation. Detailed analysis of the net reaction rates showed that
>95% of the reaction flux passed through conventional Lewis-acid
pathways
at water levels <500 ppm, even though the borane-epoxide adduct
never accounted for more than 30% of the catalyst speciation under
reaction conditions. With increasing water, as much as 80% of the
reaction flux utilized water-mediated reaction intermediates. Within
the water-mediated mechanisms, different hydrogen bond acceptors (HBAs)
influenced the reaction regioselectivity. Overall, this validated
mechanism and microkinetic model provided better understanding of
industrially important ring-opening catalysis with this catalyst in
the presence of water and could facilitate future improvement of catalyst
regioselectivity and reactivity.
Epoxide
alcoholysis is extensively employed in the synthesis of
polymers and chemical intermediates, and it generally requires an
acid catalyst for high rates and selectivity. Tris(pentafluorophenyl)borane
[B(C6F5)3] is among few catalysts
that are selective to primary alcohol products of terminal aliphatic
epoxides that do not possess any directing groups. We have previously
observed that under many conditions, the reaction regioselectivity
increases with conversion. Here, we confirm a prediction from our
earlier computational model, and we experimentally demonstrate that
this increase is due to a selectivity-enhancing role of the reaction
products. We then show that deliberate addition of catalytic amounts
of certain diols increases the reaction regioselectivity. Cis-1,2 or 1,3-diols are required to enhance selectivity,
consistent with a mechanism where extended hydrogen-bonding networks
preferentially organize the reactants. This work presents a route
to tune regioselectivity without altering the catalyst backbone and
provides another example of the role of H-bonding networks in reactions
taking place in protic media.
Density functional theory (DFT) calculations, experimental
data,
and microkinetic modeling are used to extend a triple-pathway (Lewis
acid, water-mediated, and alcohol-mediated) mechanism for tris(pentafluorophenyl)borane-catalyzed
ring opening of 1,2-epoxyoctane by alkyl alcohol nucleophiles previously
applied to 2-propanol to 1-propanol. Although simpler models may capture
overall rates, the reaction schemes proposed here are required to
explain the increasing regioselectivity to the primary product with
conversion and the dependence of the overall regioselectivity on residual
water concentration and additives as a function of reaction conditions.
The model indicates that the different reaction conditions (nucleophile,
water concentration, temperature, and conversion) lead to different
amounts of flux through alcohol-mediated pathways, different speciation
of tris(pentafluorophenyl)borane adducts, and differences among the
inherent selectivities of water-mediated mechanisms.
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