RESUMEN

Although chiral distinction plays a pervasive role in chemistry, a complete understanding of how this takes place is still lacking. In this work, we expand the earlier described minimal requirement of so called four-point interactions (vide infra). We focus on chiral point charge model systems as a means to aid in the dissection of the underlying, operative principles. We also construct models with defined symmetry characteristics. By considering extensive constellations of diastereomeric complexes, we are able to identify emerging principles for chiral distinction. As previously postulated, all the diastereomeric complexes, regardless of their nominal contact-points, possess a chiral distinction energy. In the comparison of complexes, we find that, contrary to chemical intuition, the magnitude of chiral distinction does not correlate with the stability of the complexes, i.e., consideration of low energy complexes may not be an effective way to evaluate chiral distinction. Similarly, we do not find a correlation between the number of contact-points and chiral distinction. Moreover, favorable interactions and facile chiral distinction appear to be unrelated. We also see some tendency for greater chiral distinction in less symmetric systems, although this may not be general. These studies can now form the basis to fold in higher levels of complexity into the models so as to gain further insights into the nature of chiral distinction.

Asunto(s)

Dimerización , Modelos Moleculares , Electricidad Estática , Hidrocarburos Halogenados/química , Conformación Molecular , Estereoisomerismo , Temperatura , Termodinámica

RESUMEN

Dimers of the simple chiral molecule CHFClBr have been studied using a variety of computational approaches, including HF, MP2, and DFT B3LYP and the 6-31G*, 6-31++G**, and 6-311++G** basis sets. Both heterochiral and homochiral dimers were studied to allow analysis of the chiral distinction in these systems. The dimers were arranged in edge-to-edge orientations with assorted combinations of two contact-points ("2:2e") between the dimers. The monomers were constrained to tetrahedral symmetry. We demonstrate that chiral distinction does indeed occur in these two contact-point models. While the stabilization energies are driven by the interactions of the nearest atoms (contacts) in the complexes, the degree of chiral distinction is driven by the profile of changing atoms, which, in the present systems, are often the distal atoms of the complexes. Moreover, the chiral distinction does not correlate with the stabilization energies. The terms contact-points and interactions are defined.

RESUMEN

Ab initio calculations reveal chiral distinction in two-point contact CHFCIBr dimers, with chiral distinction energy of 1.5 kJ mol-1 between the SR and SS dimers fully optimized at the MP2/6-311++G** level.