THE CALCULATION AND ANALYSIS OF ISOTOPE EFFECTS ON THE NUCLEAR SPIN-SPIN COUPLING-CONSTANTS OF METHANE AT VARIOUS TEMPERATURES

Citation
Rd. Wigglesworth et al., THE CALCULATION AND ANALYSIS OF ISOTOPE EFFECTS ON THE NUCLEAR SPIN-SPIN COUPLING-CONSTANTS OF METHANE AT VARIOUS TEMPERATURES, Molecular physics, 92(1), 1997, pp. 77-88
Citations number
43
Categorie Soggetti
Physics, Atomic, Molecular & Chemical
Journal title
ISSN journal
00268976
Volume
92
Issue
1
Year of publication
1997
Pages
77 - 88
Database
ISI
SICI code
0026-8976(1997)92:1<77:TCAAOI>2.0.ZU;2-C
Abstract
New ab initio symmetry-coordinate carbon-proton and proton-proton spin -spin coupling surfaces for the methane molecule have been computed. C alculations have been performed at the SOPPA(CCSD) level using a large -basis set and a grid of 55 geometries on the two surfaces. The nuclea r motion in the isotopomers CH4, CH3D, CH2D2, CHD3 and CD4 has been av eraged over these surfaces to give values of J(C-13,H) and J(C-13,D) f or the C-13 isotopomers and J(H,D) for the C-12 isotopomers at selecte d temperatures. Calculated isotope effects on J(C,H) and J(C,D) are ve ry close to the values observed experimentally. This validates analysi s into the various nuclear motion contributions to show that bond stre tching at first order dominates and that angle bending at second order is also significant. However, the bond-stretching terms stem from the 'other' three bonds and there is surprisingly very little contributio n from the bond containing the coupled nuclei. For the proton-deuteron coupling it is second-order bending which plays the major part but he re all contributions are very small which explains why no change in J( H,D) has ever been observed along the series CH3D, CH2D2 and CHD3. The source of non-additivity in the isotope effects on J(C,H), J(C,D) and J(H,D) is located. It is believed that the present results are the mo st accurate ab initio results for the spin-spin coupling in any polyat omic molecule, possibly the most accurate for the magnetic property of any polyatomic molecule and among the most accurate for a molecular p roperty of a pentatomic molecule.