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Quantum-connectivity indices

Fig. 2. Contribution of the aromatic rings of two polycylic aromatic hydrocarbons (PAHs) to the quantum-connectivity index CRg(p) (left) and to aqueous solubility expressed as InC ) (right). The compound at the top is benzo[a]pyrene and the one at the bottom is benz[a]anthracene. Fig. 2. Contribution of the aromatic rings of two polycylic aromatic hydrocarbons (PAHs) to the quantum-connectivity index CRg(p) (left) and to aqueous solubility expressed as InC ) (right). The compound at the top is benzo[a]pyrene and the one at the bottom is benz[a]anthracene.
The aforementioned macroscopic physical constants of solvents have usually been determined experimentally. However, various attempts have been made to calculate bulk properties of Hquids from pure theory. By means of quantum chemical methods, it is possible to calculate some thermodynamic properties e.g. molar heat capacities and viscosities) of simple molecular Hquids without specific solvent/solvent interactions [207]. A quantitative structure-property relationship treatment of normal boiling points, using the so-called CODESS A technique i.e. comprehensive descriptors for structural and statistical analysis), leads to a four-parameter equation with physically significant molecular descriptors, allowing rather accurate predictions of the normal boiling points of structurally diverse organic liquids [208]. Based solely on the molecular structure of solvent molecules, a non-empirical solvent polarity index, called the first-order valence molecular connectivity index, has been proposed [137]. These purely calculated solvent polarity parameters correlate fairly well with some corresponding physical properties of the solvents [137]. [Pg.69]

Parameters of linear equations Y = A X -)- B connecting empirical donor- acceptor parameters of organic molecules (Y) (Eqs. 24 and 25) with their quantum chemical indexes (X) from [49]... [Pg.247]

Jensen [9] indicated that there is no evidence that Drago s parameters reflect the relative electrostatic and covalent contributions to the bonding in resulting adducts. They were not correlated with either a physical property (dipole moment, ionization potential) or with a quantum-mechanically calculated index. Drago s approach is a purely empirical method of calculating enthalpy of formation for molecular adducts. Fowkes applied the Lewis E C equation [19] and has attempted to determine E and C parameters for both polymers and surfaces. However, Jensen [9] indicated the potential problem connected... [Pg.467]

Contents Introduction. - Concept of Creation and Annihilation Operators. -Particle Number Operators. - Second Quantized Representation of Quantum Mechanical Operators. - Evaluation of Matrix Elements. - Advantages of Second Quantization. - Illustrative Examples. - Density Matrices. -Connection to Bra and Ket Formalism. - Using Spatial Orbitals. - Some Model Hamiltonians in Second Quantized Form. - The Brillouin Theorem. -Many-Body Perturbation Theory. -Second Quantization for Nonorthogonal Orbitals. - Second Quantization and Hellmann-Feynman Theorem. - Inter-molecular Interactions. - Quasiparticle Transformations. Miscellaneous Topics Related to Second Quantization -Problem Solutions. - References -Index. [Pg.311]


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See also in sourсe #XX -- [ Pg.26 ]




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