Non-empirical calculations of NMR indirect carbon–carbon coupling constants: 2. Strained polycarbocycles

## Abstract High‐level __ab initio__ calculations of carbon–carbon coupling constants were carried out in tetrahedrane, prismane and cubane using the SOPPA (Second‐Order Polarization Propagator Approach) computational scheme, in good agreement with available experimental data. It was found that SOP

## Abstract A systematic study of the one‐bond and long‐range __J__(C,C), __J__(C,H) and __J__(H,H) in the series of nine bicycloalkanes was performed at the SOPPA level with special emphasis on the coupling transmission mechanisms at bridgeheads. Many unknown couplings were predicted with high rel

## Abstract A full set of carbon–carbon coupling constants have been calculated at the SOPPA level in the series of six most representative propellanes. Special attention was focused on spin–spin couplings involving both bridgehead carbons, and these data were rationalized in terms of the multipath

## Abstract Carbon–carbon spin–spin coupling constants were calculated at the SOPPA level for a series of seven classical spiroalkanes, spiro[2.2]pentane, spiro[2.3]hexane, spiro[2.4]heptane, spiro[2.5]octane, spiro[3.3]heptane, spiro[4.4]nonane and spiro[5.5]undecane, with special focus upon coupl

## Abstract Carbon–carbon and carbon–hydrogen spin–spin coupling constants were calculated in the series of the first six monocycloalkanes using SOPPA and SOPPA(CCSD) methods, and very good agreement with the available experimental data was achieved, with the latter method showing slightly better r

## Abstract A comprehensive theoretical study of nine classical caged polycycloalkanes (tetrahedrane, prismane, homoprismane, quadricyclane, cubane, pentaprismane, hexaprismane, adamantane and diamantane) was carried out with special focus on the structural behavior of their __J__(C,C) values calcu