A two force-constant model for complexes B⋯M–X (B is a Lewis base and MX is any diatomic molecule): Intermolecular stretching force constants from centrifugal distortion constants DJ or ΔJ

Abstract: A two force-constant model is proposed for complexes of the type B⋯MX, in which B is a simple Lewis base of at least C2v symmetry and MX is any diatomic molecule lying along a Cn axis (n ≥ 2) of B. The model assumes a rigid subunit B and that force constants beyond quadratic are negligible. It leads to expressions that allow, in principle, the determination of three quadratic force constants F11, F12, and F22 associated with the r(B⋯M) = r2 and r(M-X) = r1 internal coordinates from the equilibrium centrifugal … Show more

“…The compliance matrix elements ( F –1 ) nn are simply 1/ F nn under the approximations described above. It was shown in ref. 50 that zero-point constants and coordinates can be used in place of equilibrium values to a reasonable approximation.…”

“…To deal with such cases, we have recently described a two-force constant model which relates the quadratic force constants F M–X and F B···M (hereafter referred to as F 11 and F 22 , respectively) to either D e J or Δ e J under the assumption that the contribution of the cross term F 12 is negligible. 50 The model applies to all complexes of a Lewis base B with any diatomic molecule ( e.g. a hydrogen halide HX, a dihalogen XY, or a coinage metal halide MX) as long as the diatomic molecule lies along a C n ( n ≥ 2) symmetry axis of B in the equilibrium geometry.…”

“…The two-force constant model for a symmetric-top molecule such as H 3 P···AgI leads (with numbering of the Ag and I atoms and internal coordinates r 1 and r 2 shown in Fig. 2 ) to the expression 50 In eqn (3), I e bb is an equilibrium principal moment of inertia and the a n are equilibrium principal axis coordinates of atoms n = 1 and 2. The compliance matrix elements ( F –1 ) nn are simply 1/ F nn under the approximations described above.…”

H₃P⋯AgI: generation by laser-ablation and characterization by rotational spectroscopy and ab initio calculations

“…The compliance matrix elements ( F –1 ) nn are simply 1/ F nn under the approximations described above. It was shown in ref. 50 that zero-point constants and coordinates can be used in place of equilibrium values to a reasonable approximation.…”

“…To deal with such cases, we have recently described a two-force constant model which relates the quadratic force constants F M–X and F B···M (hereafter referred to as F 11 and F 22 , respectively) to either D e J or Δ e J under the assumption that the contribution of the cross term F 12 is negligible. 50 The model applies to all complexes of a Lewis base B with any diatomic molecule ( e.g. a hydrogen halide HX, a dihalogen XY, or a coinage metal halide MX) as long as the diatomic molecule lies along a C n ( n ≥ 2) symmetry axis of B in the equilibrium geometry.…”

“…The two-force constant model for a symmetric-top molecule such as H 3 P···AgI leads (with numbering of the Ag and I atoms and internal coordinates r 1 and r 2 shown in Fig. 2 ) to the expression 50 In eqn (3), I e bb is an equilibrium principal moment of inertia and the a n are equilibrium principal axis coordinates of atoms n = 1 and 2. The compliance matrix elements ( F –1 ) nn are simply 1/ F nn under the approximations described above.…”

H₃P⋯AgI: generation by laser-ablation and characterization by rotational spectroscopy and ab initio calculations

“…We recently proposed a model 43 that allows in principle some of the quadratic force constants of L· · · M-X complexes to be established from centrifugal distortion constants determined experimentally. This model goes beyond that of Millen 44 by describing the centrifugal distortion constant D J (for symmetric top or linear complexes) or ∆ J (for asymmetrictop complexes) in terms of three quadratic bond-stretching force constants F 11 , F 22 , and F 12 , where the subscripts 1 and 2, respectively, refer to the M-X and L· · · M bonds (such that F 11 = F M-X and F 22 = F L · · · M ) with F 12 being the off-diagonal coupling term.…”

Molecular geometries and other properties of H2O⋯AgI and H3N⋯AgI as characterised by rotational spectroscopy and ab initio calculations

“…The experimentally-determined force constants are calculated by applying a model 59 which accounts for contributions to the centrifugal distortion constants from both the MX and S•••M bonds. The force constants of these bonds are denoted by F11 and F22 respectively in Eq 3;…”

Geometries of H2S⋯MI (M = Cu, Ag, Au) complexes studied by rotational spectroscopy: The effect of the metal atom