A systematic density functional study of fluorination in methane, ethane and ethylene

In silico geometric and energetic data of all possible simple rotamers made of non-metal elements

This article presents theoretical data on geometric and energetic features of halogenated rotamers of the following backbone structures, C—C, N—N, P—P, O—O, S—S, N—P, O—S, C—N, C—P, C—O, C—S, N—O, N—S, P—O and P—S. The data is considered to be comprehensive combinations of non-metal elements in the form abcx–ydef whereby a,b,c,d,e,f are halogen (fluorine to iodine), hydrogen or a lone pair and x,y are carbon, nitrogen, phosphorus, oxygen and sulfur. Data were obtained from ab initio geometry optimization and frequency calculations at HF, B3LYP, MP2 and CCSD levels of theory on 6-311++G(d,p) basis set. In total, 8535 non-enantiomeric structures were produced by custom-made codes in Mathematica and Q-Chem quantum chemical package. Extracted geometric and energetic data as well as raw output files, codes and scripts associated with the data production are presented in the data repository.

The "azido gauche effect"-implications for the conformation of azidoprolines

The "azido gauche effect" was examined both experimentally and theoretically and was found to determine the conformation of, for example, (4R)- and (4S)-azidoproline (Azp) derivatives. For (4R)Azp derivatives, the azido gauche effect induces a preferred C(4)-exo conformation of the pyrrolidine ring, which leads to stabilization of the s-trans amide conformer of, e.g., Ac-(4R)Azp-OCH(3) (5R) via an n-->pi interaction between the nonbonding electrons of the oxygen of the acetyl group and the carbonyl group of the ester. For (4S)Azp derivatives, the azido gauche effect results in a C(4)-endo conformation of the pyrrolidine ring that does not allow for this stabilizing n-->pi interaction of the s-trans conformer. Consequently, a significantly higher s-trans:s-cis amide conformer ratio is observed for (4R)Azp compared to (4S)Azp derivatives (e.g., 6.1:1 versus 2.6:1 in D(2)O for Ac-(4R)Azp-OCH(3) (5R) compared to Ac-(4S)Azp-OCH(3) (5S)). These conformational preferences are reflected in the higher tendency of (4S)Azp-containing peptides to form cyclic peptides with all-cis amide bonds compared to (4R)Azp derivatives. Ab initio calculations demonstrate that the strength of the azido gauche effect is comparable to that of the well-known "fluorine gauche effect". For azidoethane derivatives N(3)-CH(2)CH(2)-X (X = N(3), NHCOH, NHAc, or N(CH(3))Ac), the ab initio calculations revealed energy differences of 5-13 kJ mol(-)(1) between the anti and gauche conformations in favor of the gauche conformer. Calculations were also performed for the (4R)Azp and (4S)Azp derivatives 5R and 5S, supporting the experimentally observed data.

Dissociative and associative mechanisms of cope rearrangements of fluorinated 1,5-hexadienes and 2,2'-bis-methylenecyclopentanes

The effects of fluorine substitution on the Cope rearrangements of 1,5-hexadiene and 2,2'-bis-methylenecyclopentane have been examined computationally using (U)B3LYP/6-31+G(d,p) and CASPT2/6-31G(d) methodology. The calculations indicate that fluorine substituents at the hexadiene termini generally stabilize the transition states relative to the ground states of the chair conformations and destabilize pathways that occur via boat conformations, in accord with the experimental observations of Dolbier. With meso-2,2'-bis(difluoromethylene)cyclopentane, this destabilization is sufficient to favor a relatively dissociative concerted transition state resembling weakly interacting allyl radicals over a normal aromatic concerted boat transition state. This preference is due partly to an increase in the activation enthalpy for the concerted rearrangement coupled with the more favorable entropy for dissociation. In octafluoro- and decafluorohexadienes, the situation is reversed, and reaction through a cyclohexane-1,4-diyl is favored. Even in the octafluoro system with no radical stabilizing substituents at C(2) and C(5), the preference of fluorine for sp(3) centers causes reaction via the cyclohexane-1,4-diyl. In establishing methodology for this study, the conformations of 1,2-difluoroethane and 1,1,2,2-tetrafluoroethane were also examined thoroughly by the B3LYP method using three basis sets.