Molecules as Networks: A Localization-Delocalization Matrices Approach

Publication date: Available online 23 November 2017 Source:Computational and Theoretical Chemistry Author(s): Chérif F. Matta Inspired by chemical graph theory (CGT), a matrix representation of molecules and reaction paths is presented within the framework of Bader’s quantum theory of atoms in molecules (QTAIM). A molecule is viewed as a network of electron delocalization channels or highways (vertices) that connect every pair of atoms in the system and electron localization cul-de-sacs loops connecting any given atom to itself. The representation of a molecule as a fuzzy, complete, non-directed graph, captured mathematically as an electron localization-delocalization matrix (an LDM), is rich with coded physical and chemical information. An LDM contains information on the bond-path molecular graph, bond strengths, molecular geometry, atomic electron populations and atomic charges, newly proposed multidimensional atomic charges, atomic volumes, free valences, NMR proton-proton coupling constants, and molecular branching. LDMs can quantify molecular similarity by matrix difference measures such as the Frobenius distance, possibly after diagonalization and/or size adjustments with ghost atoms, or by the use of principal component analysis (PCA). Because they condense information at an atomic resolution, LDMs can be used to construct predictive quantitative-structure-to-activity/property-relationship (QSAR/QSPR) models with wide range of applications including, for example,...
Source: Computational and Theoretical Chemistry - Category: Chemistry Source Type: research
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