7.10 Coupled-Cluster Excited-State and Open-Shell Methods 7.10.5 Spin-Flip Methods for Di- and Triradicals 7.10.7 EOM-DEA-CCSD

7.10.6 EOM-DIP-CCSD

(September 1, 2024)

Double-ionization potential (DIP) is another non-electron-conserving variant of EOM-CCSD. ⁷⁰⁰ Kuś T., Krylov A. I.
J. Chem. Phys.
(2011), 135, pp. 084109. Link ^, ⁷⁰¹ Kuś T., Krylov A. I.
J. Chem. Phys.
(2012), 136, pp. 244109. Link In DIP, target states are reached by detaching two electrons from the reference state:

\Psi_{k}=\hat{R}_{N-2}\Psi_{0}(N+2),

(7.80)

and the excitation operator $R$ has the following form:

\hat{R}=\frac{1}{2}\sum_{ij}r_{ij}ji+\frac{1}{6}\sum_{ijka}r_{ijk}^{a}a^{% \dagger}kji.

(7.81)

As a reference state in the EOM-DIP calculations one usually takes a well-behaved closed-shell state. EOM-DIP is a useful tool for describing molecules with electronic degeneracies of the type “ $2n-2$ electrons on $n$ degenerate orbitals”. The simplest examples of such systems are diradicals with two-electrons-on-two-orbitals pattern. Moreover, DIP is a preferred method for four-electrons-on-three-orbitals wave functions.

Accuracy of the EOM-DIP-CCSD method is similar to accuracy of other EOM-CCSD models, i.e., 0.1–0.3 eV. The scaling of EOM-DIP-CCSD is ${\cal{O}}({N^{6}})$ , analogous to that of other EOM-CCSD methods. However, its computational cost is less compared to, e.g., EOM-EE-CCSD, and it increases more slowly with the basis set size. An EOM-DIP calculation is invoked by using DIP_STATES, or DIP_SINGLETS and DIP_TRIPLETS. In certain circumstances, the DIP_AA_STATES, DIP_BB_STATES, DIP_BA_STATES keywords can be used.

Note: The performance of EOM-DIP may be poor if the reference state is unstable with respect to electron detachment. See Section 7.10.12 for details.

Note: In some applications of EOM-DIP-CCSD, only 2 $h$ operators were included in the EOM part. These calculations correspond to energies obtained from EOM_PRECONV_DOUBLES = TRUE calculation.

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7.10.6 EOM-DIP-CCSD