On the calculation of nuclear spin-spin coupling constants. The bond length dependence of the Fermi contact term in H2 and HD

## Only pomt densI& are sampIed when matnx elements of a delta funclron operator are evaluated Thus, the Ferrm contact contnbution to nuclear spin-spin couphng tensors IS very senslhve IO local ma ccurac~es of the wavefunctloas An alternauve expresslon for the delta function wiuch uses a global re

## Abstract We present calculations of indirect nuclear spin–spin coupling constants in large molecular systems, performed using density functional theory. Such calculations, which have become possible because of the use of linear‐scaling techniques in the evaluation of the Coulomb and exchange‐cor

Isokopic nuclear spti spin coupling constants have been e-&dated for ti possible couplings in HIO, NH3 and CH4 by two different double perturbation techniques. All calculations were performed employing bases of decors constructed with SCF canonical and, for H20, localized orbitals, produced by exten

Theoretical calculations performed using the coupled Hartree-Fock perturbation theory (CHFPT) show that the MNDO approximation is superior to INDO and MIND03 in computing nuclear spin coupling constants between directly bonded carbon and hydrogen in polysubstituted methanes, HCXYZ. The CHFPT-MNDO pr

Density functional theory, in particular, with the Becke-3-parameter-Lee-Yang-Parr (B3LYP) hybrid functional, has been shown to be a promising method for the calculation of indirect nuclear spin-spin coupling constants. However, no systematic investigation has so far been undertaken to evaluate the

Partially resolved hyperfine structure arising from H,Br nuclear-spin-nuclear-spin coupling has been identified in each Brnuclear quadrupole component of the l,,, +O,,,, transition of H,O...HBr. Lineshape simulation leads to a value of D,,= -23 (2) kHz for the spin-spin coupling constant for both H,