Nuclear spin-spin coupling in the spectrum of I2 at 6328 Å

The rotational \(J=1-0\) transitions of nine different isotopomers of ethinylisocyanide. \(\mathrm{H} \cdots \mathrm{C} \equiv \mathrm{C}-\mathrm{NC}\), were measured with high resolution using a pulsed molecular beam microwave Fourier transform (MB-MWFT) spectrometer. The analysis of the complex hy

Molecules with multiple bonds are challenging for computations of nuclear spin-spin coupling constants. Tbis can be referred to the asserted importance of non-contact mechanisms, to sharp geometry variations as well as to the handling of the electronic structure problem. We employ a recently develop

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,

## 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

Pulsed-nozzle, Fourier-transform microwave spectroscopy has been used to establish the ground-state spectroscopic constants &,=2734.6105(11) MHz, D,=1.49(7) kHz, DIK=35.3(4) kHz and Dj$= -230(g) kHz for the dimer (CH,),"N...HF from its rotational spectrum. The H,19F spin-spin coupling constant D zF