Fermi and Coulomb correlation effects upon the interacting quantum atoms energy partition

TL;DR

This paper investigates how Fermi and Coulomb electron correlation effects influence the energy partitioning in interacting quantum atoms, providing detailed analysis across various molecular systems to enhance understanding of covalent and intermolecular interactions.

Contribution

It introduces a method to separate Fermi and Coulomb correlation effects within the IQA energy analysis using spin-dependent matrices, applied to diverse molecular systems.

Findings

Fermi and Coulomb correlations significantly affect IQA energy components.

Spin contributions vary across different types of chemical bonds.

Analysis offers new insights into electron delocalisation and bonding mechanisms.

Abstract

The Interacting Quantum Atoms (IQA) electronic energy partition is an important method in the field of quantum chemical topology which has given important insights of different systems and processes in physical chemistry. There have been several attempts to include Electron Correlation (EC) in the IQA approach, for example, through DFT and Hartree-Fock/Coupled-Cluster (HF/CC) transition densities. This work addresses the separation of EC in Fermi and Coulomb correlation and its effect upon the IQA analysis by taking into account spin-dependent one- and two-electron matrices $D^{\mathrm{HF/CC}}_{p\sigma q \sigma}$ and $d^{\mathrm{HF/CC}}_{p\sigma q\sigma r\tau s\tau}$ wherein $\sigma$ and $\tau$ represent either of the $\alpha$ and $\beta$ spin projections. We illustrate this approach by considering BeH$_2$,BH, CN$^-$, HF, LiF, NO$^+$, LiH, H$_2$O$\cdots$H$_2$O and C$_2$H$_2$, which comprise non-polar covalent, polar covalent, ionic and hydrogen bonded systems. The same and different spin contributions to ($i$) the net, interaction and exchange-correlation IQA energy components and ($ii$) delocalisation indices defined in the quantum theory of atoms in molecules are carefully examined and discussed. Overall, we expect that this kind of analysis will yield important insights about Fermi and Coulomb correlation in covalent bonding, intermolecular interactions and electron delocalisation in physical chemistry.