Structures, Energies, and Spin–Spin Coupling Constants of Methyl-Substituted 1,3-Diborata-2,4-diphosphoniocyclobutanes: Four-member B–P–B–P Rings B2P2(CH3)nH8–n, with n = 0, 1, 2, 4
journal contributionposted on 29.09.2011 by Janet E. Del Bene, Ibon Alkorta, José Elguero
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An ab initio study has been carried out to determine the structures, relative stabilities, and spin–spin coupling constants of a set of 17 methyl-substituted 1,3-diborata-2,4-diphosphoniocyclobutanes B2P2(CH3)nH8–n, for n = 0, 1, 2, 4, with four-member B–P–B–P rings. The B–P–B–P rings are puckered in a butterfly conformation, in agreement with experimental data for related molecules. Isomers with the CH3 group bonded to P are more stable than those with CH3 bonded to B. If there is only one methyl group or if two methyl groups are bonded to two different P or B atoms, isomers with equatorial bonds are more stable than those with axial bonds. However, when two methyl groups are present, the gem isomers are the most stable for molecules B2P2(CH3)2H6 with P–C and B–C bonds, respectively. Transition structures present barriers to the interconversion of two equilibrium structures or to the interchange of axial and equatorial positions in the same isomer. These barriers are very low for the isomer with two methyl groups bonded to B in axial positions for the isomer with four axial bonds and for the isomer with geminal B–C bonds at both B atoms. Coupling constants 1J(B–P), 1J(P–C), 1J(B–C), 2J(P–P), and 3J(P–C) are capable of providing structural information. They are sensitive to the number of methyl groups present and can discriminate between axial, equatorial, and geminal bonds, although not all do this to the same extent. The one-bond coupling constants 1J(B–P), 1J(P–C), and 1J(B–C) are similar in equilibrium and transition structures, but 3J(P–C) and 2J(P–P) are not. These coupling constants and those of the corresponding fluoro-derivatives of the 1,3-diborata-2,4-diphosphoniocyclobutanes demonstrate the great sensitivity of phosphorus coupling to structural and electronic effects.