Review of biorthogonal coupled cluster representations for electronic excitation

TL;DR

This paper systematically analyzes biorthogonal coupled cluster (bCC) methods for electronic excitation, focusing on truncation errors, separability, and comparing bCC with other excited-state methods to highlight its advantages and limitations.

Contribution

It provides a comprehensive, generalized analysis of bCC representations, deriving formulas for truncation errors and examining separability properties, extending previous studies.

Findings

bCC methods have specific truncation error characteristics.

Separable transition moments depend on the dual ground state.

bCC shows advantages over CI but weaker properties than full ISR methods.

Abstract

Single reference coupled-cluster (CC) methods for electronic excitation are based on a biorthogonal representation (bCC) of the (shifted) Hamiltonian in terms of excited CC states, also referred to as correlated excited (CE) states, and an associated set of states biorthogonal to the CE states, the latter being essentially configuration interaction (CI) configurations. The bCC representation generates a non-hermitian secular matrix, the eigenvalues representing excitation energies, while the corresponding spectral intensities are to be derived from both the left and right eigenvectors. Using the perspective of the bCC representation, a systematic and comprehensive analysis of the excited-state CC methods is given, extending and generalizing previous such studies. Here, the essential topics are the truncation error characteristics and the separability properties, the latter being crucial for designing size-consistent approximation schemes. Based on the general order relations for the bCC secular matrix and the (left and right) eigenvector matrices, formulas for the perturbation-theoretical (PT) order of the truncation errors (TEO) are derived for energies, transition moments, and property matrix elements of arbitrary excitation classes and truncation levels. In the analysis of the separability properties of the transition moments, the decisive role of the so-called dual ground state is revealed. Due to the use of CE states the bCC approach can be compared to so-called intermediate state representation (ISR) methods based exclusively on suitably orthonormalized CE states. As the present analysis shows, the bCC approach has decisive advantages over the conventional CI treatment, but also distinctly weaker TEO and separability properties in comparison with a full (and hermitian) ISR method.