Conformational and Substituent Effects on The Rehybridization of Boron in β‐Substituted Ethylboranes

Abstract

AbstractThe chemistry of boron‐containing molecules pervades the study of biomolecules, new materials, organic synthesis, and beyond. In addition, the stereochemistry and rehybridization capability of boron in molecules influence the reactivity and selectivity of reactions. Therefore, conformational analysis and the study of substituent effects on the modulation of the sp2–sp3 character of boron in β‐substituted ethylboranes may be valuable for the rational design of compounds in which the empty pB orbital plays a central role in the reaction intermediate. Accordingly, we have quantum‐chemically studied the orbital interactions and bonding properties that govern the conformational behavior and boron hybridization in β‐substituted ethylboranes (substituents, X=H, CH3, F, Cl, NH2, PH2, OH, and SH). Conformations with an anti arrangement along the B−C−C−X path are generally preferred over syn and/or gauche conformations, while a B−H bond tends to eclipse with the C−C bond rather than with a less sterically hindered C−H bond. However, the s character of boron relative to the C−B bond strongly decreases in the syn conformation, where X can participate as an electron donor to the empty pB orbital. Indeed, such interaction makes the syn conformation of 2‐aminoethylborane the single stable conformer in the gas phase.