Journal
JOURNAL OF CHEMICAL THEORY AND COMPUTATION
Volume 14, Issue 1, Pages 92-103Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acs.jctc.7b00931
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Funding
- NSF [CHE-1464804]
- David and Lucile Packard Foundation Fellowship
- Division Of Chemistry
- Direct For Mathematical & Physical Scien [1464804] Funding Source: National Science Foundation
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Chemical bonding plays a central role in the description and understanding of chemistry. Many methods have been proposed to extract information about bonding from quantum chemical calculations, the majority of them resorting to molecular orbitals as basic descriptors. Here, we present a method called self-attractive Hartree (SAH) decomposition to unravel pairs of electrons directly from the electron density, which unlike molecular orbitals is a well-defined observable that can be accessed experimentally. The key idea is to partition the density into a sum of one-electron fragments that simultaneously maximize the self-repulsion and maintain regular shapes. This leads to a set of rather unusual equations in which every electron experiences self-attractive Hartree potential in addition to an external potential common for all the electrons. The resulting symmetry breaking and localization are surprisingly consistent with chemical intuition. SAH decomposition is also shown to be effective in visualization of single/multiple bonds, lone pairs, and unusual bonds due to the smooth nature of fragment densities. Furthermore, we demonstrate that it can be used to identify specific chemical bonds in molecular complexes and provides a simple and accurate electrostatic model of hydrogen bonding.
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