0000000000160856
AUTHOR
A. Boutalib
G2(MP2) study of the substituent effects in the H3BXHnMe3−n (X=N, P; n=0–3) donor–acceptor complexes
Abstract The complexation energies of H 3 BXH n Me 3− n (X=N, P; n =0–3) donor–acceptor complexes have been investigated at the G2(MP2) level of theory. MP2(Full)/6-31G(d) optimized geometries and G2(MP2) calculated complexation energies are in good agreement with experiment. Increasing methyl substitutions on `X' donor atom augments both the basicity of XH n Me 3− n Lewis bases and the stability of complex. The NBO partitioning scheme suggests that there is no correlation between the charge transfer and the complexation energies.
Synthesis, Reactivity and Theoretical Study of B3H8−and Related Derivatives
Abstract Octahydrotriborate salts, B3H8 −, have been prepared by the reaction of NaBH4 with Lewis acids such as BX3·BDMA (BDMA = benzyldimethylamine, × = Cl,Br) or C2H5I in diglyme. The presence of BH3·BDMA as a by-product in the former reaction provides new insight into the reaction mechanism of B11H14 − formation. In acetonitrile-water solutions of HCl or CH3CO2H, the B3H8 − anion reacted to give B3H7CH3CN or B3H7CH3CO2 − characterized by 11B NMR spectroscopy. Their kinetic hydrolysis study was consistent with NMR analysis. Reaction of Bu4NB3H8 and CuCl2 at 0°C produced pure B3H6Cl2 −. An AM1 theoretical study of the substituted derivatives B3H7L (L = Cl−, CH3CN, CH3CO2 −, OH−) and B3H6L2…
Substituent effect on ammonia–borane donor–acceptor complexes: a G2(MP2) molecular orbital study
Abstract H3BNHnMe3−n and Me3−nHnBNH3 (n=0–3) donor–acceptor complexes have been studied using the G2(MP2) method. Predicted equilibrium structures and dissociation energies have been correlated to the degree of substitution on the donor and the acceptor separately. It is found that successive methyl substitutions on boron reduce the dissociation energies of the complexes, contrary to the successive substitutions on nitrogen. The NBO partitioning scheme suggests that there is no correlation between the charge transfer and the dissociation energies. These results are interpreted in terms of the changes in the HOMO−LUMO gap, the type of acceptor and donor involved, and distortion of the accept…
A G2 study of H3BXHn (X=N, O, F, P, S, and Cl) donor–acceptor complexes
Abstract Complexation energies of H3BXHn complexes (X=N, O, F, P, S, and Cl; n=1, 2, 3) have been computed at the G2 level of theory. G2 results show that the H3BXH3 (X=N, P) complexes are more stable than H3BXH2 (X=O, S) and H3BXH (X=F, Cl) ones. This stability was related completely either to the nature of donor compounds, and to the pyramidalization of the monoborane. Two linear correlations were established. The first one is between experimental proton affinity of the XHn donor compounds, and complexation energies of the H3BXHn complexes. The second correlation is between the ∠HBH bond angles and the complexation energies of the H3BXHn complexes calculated at the G2 level of theory.
Ab initio molecular orbital study of the substituent effect on ammonia and phosphine–borane complexes
Abstract The complexation energies of H 3 BXH 3− n F n ( X =N, P; n =0–3) and the proton affinities of XH 3– n F n compounds have been investigated at the G2(MP2) level of theory. The G2(MP2) results show that the phosphine complexes are more stable than the corresponding ammonia ones. Increasing fluorine substitution on nitrogen atom reduces both the basicity of NH 3− n F n and the stability of ammonia complexes. For the phosphine complexes, the successive fluorine substitution on the phosphine increase the stability of H 3 BPH 3− n F n complexes although the reduction of the basicity of the PH 3– n F n ligands with this substitution. The NBO partitioning scheme shows that the stability of…
Ab initio molecular orbital study of the substituent effect on phosphine–borane complexes
Abstract Ab initio molecular orbital calculations have been used to study the substituent effect on H 3 BPH n Me 3− n and Me 3− n H n BPH 3 ( n =0–3) phosphine–borane complexes. The ab initio results show that successive methyl substitution on the phosphine favours complex formation, contrary to successive methyl substitution on the borane. The natural bond orbitals partitioning scheme suggests that, in general, there is no correlation between the charge transfer and the complexation energies. It also shows the shortening of the P–H and P–C bond lengths, upon complexation, is due to the increasing `s' character of these bonds.
G2(MP2) Investigation of Alane-[X(CH3)3]- (X = C, Si, and Ge) and Alane-Y(CH3)3 (Y = N, P, and As) Interactions
Alane-[X(CH3)3]- (X = C, Si, and Ge) and alane-Y(CH3)3 (Y = N, P, and As) have been investigated as donor−acceptor complex types at the G2(MP2) level of theory. The results show that the anionic complexes are more stable than the neutral ones. They show also that this stability decreases when going from carbon to germanium for [H3AlX(CH3)3]- complexes and from nitrogen to arsenic for H3AlY(CH3)3 complexes. The interaction diagrams prove that the evolution of complexation energy depends on the coordination mode. In fact, it is a result of two interaction types: interaction between “a1” symmetry fragment molecular orbital (stabilizing) and interactions between “e” symmetry fragment molecular…
G2(MP2) molecular orbital study of the substituent effect in the H3BPH3−nFn (n=0–3) donor–acceptor complexes
Abstract The complexation energies of H3BPH3−nFn (n=0–3) and the proton affinities of PH3−nFn compounds have been investigated at the G2(MP2) level of theory. G2(MP2) results show that the successive fluorine substitution on the phosphine increases the stability of H3BPH3−nFn complexes although the basicity of the PH3−nFn ligands reduces with this substitution. The NBO partitioning scheme shows that this stability was related to the hyperconjugation effect. It proves also that the shortening of the P–H and P–F bond lengths, upon complexation, is due to an increasing `s' character in these bonds.
Stability of Borane−Adduct Complexes: A G-2 Molecular Orbital Study
Complexation energies of H3BXHn and [H3BXHn-1]- complexes (X = N, O, F, P, S, and Cl) (n = 3, 2, 1) have been computed at the G-2 level of theory. The formation of H3BXH3 (X = N, P) is found to be more favored than the formations of H3BXH2 (X = O, S) and H3BXH (X = F, Cl). The qualitative features of the molecular orbital interaction (the correlation diagrams) of H3BNH3 (C3v symmetry group), H3BOH2 (Cs symmetry group), and H3BFH (Cs symmetry group) complexes are presented. These diagrams show that the σ character of the B−X bond decreases and the π character increases when the electronegativity of X increases and indicate that the B−X bond cannot be treated only in terms of the simplest mod…