Molecular recognition, binding and catalysis are often mediated by non-covalent interactions involving aromatic functional groups. Although the relative complexity of these so-called π interactions has made them challenging to study, theory and modelling have now reached the stage at which we can explain their physical origins and obtain reliable insight into their effects on molecular binding and chemical transformations. This offers opportunities for the rational manipulation of these complex non-covalent interactions and their direct incorporation into the design of small-molecule catalysts and enzymes.
The enantioselective Pd-catalyzed redox-relay Heck arylation of acyclic alkenyl alcohols allows access to various useful chiral building blocks from simple olefinic substrates. Mechanistically, after the initial migratory insertion, a succession of β-hydride elimination and migratory insertion steps yields a saturated carbonyl product instead of the more general Heck product, an unsaturated alcohol. Here, we investigate the reaction mechanism, including the relay function, yielding the final carbonyl group transformation. M06 calculations predict a ΔΔG‡ of 1 kcal/mol for the site selectivity and 2.5 kcal/mol for the enantioselectivity, in quantitative agreement with experimental results. The site selectivity is controlled by a remote electronic effect, where the developing polarization of the alkene in the migratory insertion transition state is stabilized by the C–O dipole of the alcohol moiety. The enantioselectivity is controlled by steric repulsion between the oxazoline substituent and the alcohol-bearing alkene substituent. The relay effeciency is due to an unusually smooth potential energy surface without high barriers, where the hydroxyalkyl-palladium species acts as a thermodynamic sink, driving the reaction toward the carbonyl product. Computational predictions of the relative reactivity and selectivity of the double bond isomers are validated experimentally.
The use of computed interaction energies and distances as parameters in multivariate correlations is introduced for postulating noncovalent interactions. This new class of descriptors affords multivariate correlations for two diverse catalytic systems with unique noncovalent interactions at the heart of each process. The presented methodology is validated by directly connecting the noncovalent interactions defined through empirical dataset analyses to the computationally derived transition states.
The mechanism of the redox-relay
Heck reaction was investigated
using deuterium-labeled substrates. Results support a pathway through
a low energy palladium–alkyl intermediate that immediately
precedes product formation, ruling out a tautomerization mechanism.
DFT calculations of the relevant transition structures at the M06/LAN2DZ+f/6-31+G*
level of theory show that the former pathway is favored by 5.8 kcal/mol.
Palladium chain-walking toward the alcohol, following successive β-hydride
eliminations and migratory insertions, is also supported in this study.
The stereochemistry of deuterium labels is determined, lending support
that the catalyst remains bound to the substrate during the relay
process and that both cis- and trans-alkenes form from β-hydride elimination.
The enantioselective 1,1-diarylation of terminal alkenes is reported herein enabled by the combination of palladium catalysis with a chiral anion phase-transfer strategy. The reaction of substituted benzyl acrylates with aryldiazonium salts and arylboronic acids gave the corresponding 3,3-diaryl propanoates in moderate to good yields and high enantioselectivies (up to 98:2 er). Substituents on the benzyl acrylate and chiral anion phase-transfer catalyst significantly affect the enantioselectivity, and multidimensional parameterization identified correlations suggesting structural origins for high stereocontrol.
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