Browsing by Author "Nori-Shargh, Davood"
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Article Citation Count: 8Conformational behaviors of trans-2,3-and trans-2,5-dihalo-1,4-diselenanes. A complete basis set, hybrid-density functional theory study and natural bond orbital interpretations(Springer, 2014) Kayı, Hakan; Mousavi, Seiedeh Negar; Kayi, Hakan; Chemical EngineeringComplete basis set CBS-4, hybrid-density functional theory (hybrid-DFT: B3LYP/6-311+G**) based methods and natural bond orbital (NBO) interpretations have been used to examine the contributions of the hyperconjugative, electrostatic, and steric effects on the conformational behaviors of trans-2,3-dihalo-1,4-diselenane [halo = F (1), Cl (2), Br (3)] and trans-2,5-dihalo-1,4-diselenane [halo = F (4), Cl (5), Br (6)]. Both levels of theory showed that the axial conformation stability, compared to its corresponding equatorial conformation, decreases from compounds 1 -> 3 and 4 -> 6. Based on the results obtained from the NBO analysis, there are significant anomeric effects for compounds 1-6. The anomeric effect associated with the electron delocalization is in favor of the axial conformation and increases from compounds 1 -> 3 and 4 -> 6. On the other hand, dipole moment differences between the axial and equatorial conformations [Delta(mu(eq) - mu(ax))] decrease from compounds 1 -> 3. Although Delta(mu(eq)-mu(ax)) parameter decreases from compound 1 to compound 3, the dipole moment values of the axial conformations are smaller than those of their corresponding equatorial conformations. Therefore, the anomeric effect associated with the electron delocalizations (for halogen-C-Se segments) and the electrostatic model associated with the dipole-dipole interactions fail to account for the increase of the equatorial conformations stability on going from compound 1 to compound 3. Since there is no dipole moment for the axial and equatorial conformations of compounds 4-6, consequently, the conformational preferences in compounds 1-6 is in general dictated by the steric hindrance factor associated with the 1,3-syn-axial repulsions. Importantly, the CBS-4 results show that the entropy difference (Delta S) between the equatorial axial conformations increases from compounds 1 -> 3 and 4 -> 6. This fact can be explained by the anomeric effect associated with the electron delocalization which affects the C-2-Se bond orders and increase the rigidity of the corresponding rings. The Gibbs free energy difference values between the axial and equatorial conformations (i.e. Delta G(ax-ax) and Delta G(eq-eq)) of compounds 1 and 4, 2 and 5 and also 3 and 6 have been calculated. The correlations between the anomeric effect, electrostatic model, Delta G(eq-ax), Delta G(ax-ax), Delta G(eq-eq), bond orders, dipole-dipole interactions, structural parameters and conformational behaviors of compounds 1-6 have been investigated.Article Citation Count: 3Correlations between hardness, electrostatic interactions, and thermodynamic parameters in the decomposition reactions of 3-buten-1-ol, 3-methoxy-1-propene, and ethoxyethene(Springer/plenum Publishers, 2015) Kayı, Hakan; Nori-Shargh, Davood; Kayi, Hakan; Javid, Nargess Rezaei; Chemical EngineeringDecomposition of the three isomeric compounds, 3-buten-1-ol (1), 3-methoxy-1-propene (2), and ethoxyethene (3), at two different (300 and 550 K) temperatures has been investigated by means of ab initio molecular orbital theory (MP2/6-311+G**//B3LYP/6-311+G**), hybrid-density functional theory (B3LYP/6-311+G**), the complete basis set, nuclear magnetic resonance analysis, and the electrostatic model associated with the dipole-dipole interactions. All three levels of theory showed that the calculated Gibbs free energy differences between the transition and ground state structures (Delta G (not equal)) increase from compound 1 to compound 3. The variations of the calculated Delta G (not equal) values can not be justified by the decrease of the calculated global hardness (eta) differences between the ground and transition states structures (i.e., Delta[eta(GS)-eta(TS)]). Based on the synchronicity indices, the transition state structures of compounds 1-3 involve synchronous aromatic transition structures, but there is no significant difference between their calculated synchronicity indices. The optimized geometries for the transition state structures of the decomposition reactions of compounds 1-3 consist in chair-like six-membered rings. The variation of the calculated activation entropy (Delta S (not equal)) values can not be justified by the decrease of Delta[eta(GS)-eta(TS)] parameter from compound 1 to compound 3. On the other hand, dipole moment differences between the ground and transition state structures [Delta(A mu (TS)-A mu (GS))] decrease from compound 1 to compound 3. Therefore, the electrostatic model associated with the dipole-dipole interactions justifies the increase of the calculated Delta G (not equal) values from compound 1 to compound 3. The correlations between Delta G (not equal), Delta[eta(GS)-eta(TS)], (Delta S (not equal)), k(T), electrostatic model, and structural parameters have been investigated.Article Citation Count: 6Natural bond orbital, nuclear magnetic resonance analysis and hybrid-density functional theory study of σ-aromaticity in Al2F6, Al2Cl6, Al2Br6 and Al2I6(Springer, 2013) Kayı, Hakan; Yahyaei, Hooriye; Mousavi, Seiedeh Negar; Maasoomi, Akram; Kayi, Hakan; Chemical EngineeringNatural bond orbital (NBO), nuclear magnetic resonance (NMR) analysis and hybrid-density functional theory based method (B3LYP/Def2-TZVPP) were used to investigate the correlation between the nucleus-independent chemical shifts [NICS, as an aromaticity criterion], sigma (Al(1)-X2(b)) -> sigma*(Al(3)-X4(b)) electron delocalizations and the dissociation energies of Al2F6, Al2Cl6, Al2Br6 and Al2I6 to 2AlX(3) (X = F, Cl, Br, I). The results obtained showed that the dissociation energies of Al2F6, Al2Cl6, Al2Br6 and Al2I6 decrease from Al2F6 to Al2I6. Like aromatic molecules, these compounds have relatively significant negative NICSiso(0) values. Clearly, based on magnetic criteria, they exhibit aromatic character and make it possible to consider them as sigma-delocalized aromatic species, such as Mobius sigma-aromatic species. The sigma-aromatic character which is demonstrated by their NICSiso(0) values decreases from Al2F6 to Al2I6. The NICSiso values are dominated by the in-plane sigma(22) (i.e., sigma(yy,) the plane containing halogen atoms bridged) chemical shift components. The increase of the NICSiso values explains significantly the decrease of the corresponding dissociation energies of Al2F6, Al2Cl6, Al2Br6 and Al2I6. Importantly, the NBO results suggest that in these compounds the dissociation energies are controlled by the stabilization energies associated with sigma (Al(1)-X2(b)) ->sigma*(Al(3)-X4(b)) electron delocalizations. The decrease of the stabilization energies associated with sigma (Al(1)-X2(b)) ->sigma*(Al(3)-X4(b)) electron delocalizations is in accordance with the variation of the calculated NICSiso values. The correlations between the dissociation energies of Al2F6, Al2Cl6, Al2Br6 and Al2I6, sigma (Al(1)-X2(b)) ->sigma*(Al(3)-X4(b)) electron delocalizations, natural atomic orbitals (NAOs) and NICSiso values have been investigated.