Computational Methods in Organometallic Catalysis. Yu Lan

Computational Methods in Organometallic Catalysis - Yu Lan


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and mPW2PLYP, Kohn–Sham unoccupied orbitals are used to calculate MP2‐type correlation functional [59, 60].

      Dispersion interactions are generally described as the interaction between instantaneous dipole moments within the electron distributions of two atoms or molecules. The simplest model of dispersion is the interaction between two Drude oscillators, where the instantaneous dipole moments of the oscillators cause a stabilizing interaction between them.

      The dispersion energy, Edisp, between two atoms or molecules at large separation takes the form of a series expansion

upper E Subscript disp Baseline equals minus StartFraction upper C 6 Over upper R Superscript 6 Baseline EndFraction minus StartFraction upper C 8 Over upper R Superscript 8 Baseline EndFraction minus StartFraction upper C 10 Over upper R Superscript 10 Baseline EndFraction minus midline-horizontal-ellipsis

      The dispersion coefficients can be determined experimentally or theoretically. Also, there are several approximate methods to evaluate the dispersion coefficients such as the London, Slater–Kirkwood, and Salem models. In most of the cases, dispersion attraction is modeled by the first term in the series only. For example, in molecular mechanics (MM) force fields, commonly used in biochemistry, a Lennard–Jones 6–12 potential is used to describe nonbonded interactions with the R6 term accounting for dispersion attraction and the R12 term corresponding to Pauli repulsion.

      Most of the classical density functionals (e.g. B3LYP) cannot describe the dispersion interaction because the long‐range behavior of the correlation functional is not correct. Therefore, the results used to study dispersion‐dominated problems are poor, such as physical adsorption, molecular conformations, ligand coordination, ligand–substrate interaction, and π‐stacking; however, those systems are important in organometallic chemistry. Indeed, classical density functionals reveal poor dispersion interaction is due to the incorrect behavior of the exchange–correlation functional in the medium and long range, especially in the long range, which results in the failure of van der Waals C6/R6 behavior.

Schematic illustration of the frequently used approaches for the dispersion correction of density functionals.
Properties vdW‐DF DF DFT‐D DCACP LAP/DCP
Correct R−6 Yes No Yes No
Thermochemistry Yes Yes
Numerical complexity High Medium Low Low
Simple forces No Yes Yes Yes
System dependency Yes Yes Yes No
Electronic effect Yes Yes No Yes
Empiricism Low Medium Medium High
Analysis insight No Good

      2.3.1 General View of Basis Set

      In quantum chemistry calculations, a common approach is to represent a molecular orbital as a LCAO

upper Psi Subscript i Baseline equals <hr><noindex><a href=Скачать книгу