# Distinguishing Artificial and Essential Symmetry Breaking in a Single   Determinant: Approach and Application to the C$_{60}$, C$_{36}$, and C$_{20}$   Fullerenes

**Authors:** Joonho Lee, Martin Head-Gordon

arXiv: 1812.05266 · 2019-03-27

## TL;DR

This paper analyzes symmetry breaking in fullerene molecules using multiple quantum chemistry methods to distinguish between artificial and essential symmetry breaking, highlighting the effectiveness of the $ppa$-OOMP2 method in identifying strong correlation.

## Contribution

It introduces a comprehensive approach combining several probes to differentiate artificial from essential symmetry breaking in fullerenes, demonstrating the utility of $ppa$-OOMP2 in this context.

## Key findings

- C36 exhibits genuine strong correlation and symmetry breaking.
- C60 shows artificial symmetry breaking, not strongly correlated.
- C20 (Ih) is strongly correlated, others show artificial breaking.

## Abstract

We present a thorough analysis of symmetry breaking observed in Hartree-Fock (HF) solutions of fullerenes C$_{60}$, C$_{36}$, and C$_{20}$ in order to characterize the nature of electron correlation in them. Our analysis is based on (1) the critical regularization strength to restore symmetry breaking in the recently developed regularized orbital optimized second-order M{\o}ller-Plesset perturbation theory ($\kappa$-OOMP2), (2) singlet-triplet gaps from various MP2 methods, and (3) natural orbital occupation numbers from restricted coupled-cluster with singles and doubles (RCCSD) and coupled-cluster valence bond with singles and doubles (CCVB-SD). Based on these three independent probes, we conclude that C$_{36}$ (D$_\text{6h}$) exhibits genuine strong correlation and symmetry breaking whereas C$_{60}$ exhibits {\it artificial} HF symmetry breaking and is not strongly correlated. Investigating the critical regularization strength, we discuss strong correlation in C$_{20}$ at the Jahn-Teller distorted geometries (C$_\text{2h}$, D$_\text{2h}$, C$_\text{i}$, and D$_\text{3h}$) and the I$_\text{h}$ geometry. Only C$_{20}$ (I$_\text{h}$) was found to be strongly correlated while others exhibit {\it artificial} HF symmetry breaking. This analysis highlights a useful feature of the recommended $\kappa$-OOMP2 method. It is an electronic structure method that describes dynamic correlation, and attenuates strong correlation in MP2 towards zero by regularization. Therefore, $\kappa$-OOMP2 will exhibit symmetry breaking in its reference determinant only when correlation is strong (i.e., essential symmetry breaking). Artificial symmetry breaking (arising in HF due to neglect of dynamic correlation) is thus removed in $\kappa$-OOMP2.

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Source: https://tomesphere.com/paper/1812.05266