7.3.5 TDDFT + PCM for Excitation and Emission Energies in Solution

LR-PCM for TDDFT is activated by setting TDDFT_LR_PCM = TRUE in the $pcm section. The default is a nonequilibrium calculation employing the optical dielectric constant ${\epsilon }_{\mathrm{\infty }}$ for the excited state, whereas the static dielectric constant is employed for the ground-state solvation of the used MOs. This corresponds to the “full linear response theory” of Ref.  798 Liu J., Liang W.
J. Chem. Phys.
(2013), 138, pp. 024101. Link . The value of ${\epsilon }_{\mathrm{\infty }}$ is specified using the keyword OpticalDielectric in the $solvent input section, or can be chosen from a list of preset values as described in Section 11.2.4.3; an equilibrium calculation in the excited state could be requested by setting OpticalDielectric equal to the value of the solvent’s static dielectric constant.

A perturbative approximation to full LR-PCM is also available, along with state-specific corrections that are somewhat more theoretically rigorous, ⁵²⁹ Herbert J. M.
Wiley Interdiscip. Rev.: Comput. Mol. Sci.
(2021), 11, pp. e1519. Link and have also been implemented for TDDFT. ⁸⁷⁹ Mewes J.-M. et al.
J. Phys. Chem. A
(2015), 119, pp. 5446. Link ^{, 1420} You Z.-Q. et al.
J. Chem. Phys.
(2015), 143, pp. 204104. Link This approach is described in further detail below in Sections 7.3.5.2 and 11.2.3.3. If the C-PCM model is used, then analytical excited-state energy gradients are available for TDDFT + LR-PCM and are automatically used if LR-PCM is activated for TDDFT geometry optimization. As excited-state geometry optimization presupposes equilibration of the solute structure in the excited state, it is probably appropriate to employ the static dielectric constant for geometry optimization.

The LR-PCM approach considers the solvent response to the electronic transition density and provides only for optically-allowed transitions a non-vanishing contribution. Optically-forbidden transitions should be described with a state-specific PCM. This includes triplet excited states accessed from a singlet ground state and also charge-transfer states with a vanishing transition density

The state-specific PCM jobs are controlled with the StateSpecific keyword in the $pcm block, which can be employed to activate either a perturbative or one of the iterative SS-PCMs.

1. Perturbative State-Specific (ptSS) PCM

Perturbative state-specific PCM (ptSS-PCM) is activated by setting StateSpecific = Perturb in the $pcm block. By default, the ptSS correction is evaluated in the nonequilibrium regime governed by the optical dielectric constant (OpticalDielectric in the $solvent block). To force an equilibrium ptSS-PCM calculation, OpticalDielectric must be set to the static value, ${\epsilon }_0$. To separate the fast and slow contributions to the reaction field, the charge-separation procedure is chosen with the ChargeSeparation keyword (Marcus is the default, for more information, see Section 11.2.3.3). Alternatively, setting NonEquilibrium = TRUE results in a default nonequilibrium ptSS-PCM calculation with Marcus charge separation and deactivated LR-PCM. The ptSS-PCM output provides for each calculated state both a ptSS and a ptLR-correction. In the nonequilibrium case, the corrected energy corresponds to the vertical excitation energy. Results are provided both with the unrelaxed density and the relaxed density, if the latter has been recommended. Results based on the relaxed density are recommended. ¹⁴²⁰ You Z.-Q. et al.
J. Chem. Phys.
(2015), 143, pp. 204104. Link

2. Iterative State-Specific PCM

The control options for iterative state-specific PCM follow the same setup as for the ADC($n$)-family of methods described in Section 7.11.10. By setting the keyword EqSolv to the intended maximum number of iterations, self-consistent SS-PCM is activated for the reference state indicated in EqState. Iterations are performed until either the maximum number of iterations is reached or the convergence criteria are satisfied. These criteria are based on the excited-state energy and the surface charges and are set using Eqs_Conv. During the iterative optimization of the reaction field, states may change their ordering (root-flipping). Automatic state-following (EqState_Follow = true) based on a combination of the electrostatic potential at the surface, the energy changes, and excited state dipole moments is available. It performs well for separated states or states of substantially different character (i.e. charge-transfer and locally excited states) but can break down for similar states close to their crossing points.

Note that the excited state energy with iterative state-specific PCMs is only physically meaningful for the reference state (marked in the output as “EqS-reference”). For all other states, only energies relative to the self-consistent reference state can be interpreted. The iterative equilibrium SS-PCM output lists the emission energy to the ground state (only EI-SS-PCM), as well as transition energies to the other excited states (both EI- and II-SS-PCM) in zeroth- and first-order (with nonequilibrium ptSS correction). For nonequilibrium II-SS-PCM, only the vertical excitation energy to the self-consistently optimized excited state is physically meaningful. For the nonequilibrium II-SS-PCM and ptSS-PCM calculations, again the ChargeSeparation keyword is employed.

2. (A) External-Iteration SS-PCM

EI-SS-PCM, otherwise known as Improta-Barone-Scalmani-Frisch PCM, ⁵⁷⁶ Improta R. et al.
J. Chem. Phys.
(2007), 127, pp. 074504. Link is activated by setting StateSpecific = External in the $pcm section. EI-SS-PCM iterates over both the SCF and TDDFT calculation by returning the excited-state reaction field into a frozen-Reaction-Field (fRF) SCF. Prior to this, the reaction field has to be set up in a separate job by setting StateSpecific = External without adding the keyword EqSolv. In the following iterative job, the reference state (EqState) can then be chosen freely among the states calculated prior, and iterations can be restarted in the same way (e.g., to manually correct the automatic state-following). The EI-SS-PCM convergence is judged based on the change in the surface charge vector and the fRF-SCF energy, in order to converge all excited states to the same level. Additionally, the self-ptSS term indicates convergence though it is not used as an actual convergence criterion.

EI-SS-PCM is always performed as equilibrium solvation employing the full dielectric response of the solvent based on the static dielectric constant (Dielectric). Non-equilibrium emission and transition energies are calculated in first order at the ptSS-PCM level. EI-SS-PCM provides the correct solution of the state-specific Schrödinger equation without contamination from the ground state MOs, and hence, should be used whenever the excited state is to be treated on equal footing with the ground state.

2. (B) Internal-Iteration SS-PCM

II-SS-PCM, otherwise known as the vertical excitation model (VEM), ⁸⁵⁰ Marenich A. V. et al.
Chem. Sci.
(2011), 2, pp. 2143. Link is activated by setting the keyword StateSpecific = Internal. II-SS-PCM retains the same ground state wave-function in the iterations but exchanges the ground and excited-state reaction field during the TDDFT calculation. This leads to slight contamination of the excited state by the ground state MOs. II-SS-PCM is available both for equilibrium (adiabatic excitation model, AEM) and nonequilibrium (VEM), and with either the full matrix (f) or only the diagonal elements (d) of the excited state reaction field, as described in Ref.  850 Marenich A. V. et al.
Chem. Sci.
(2011), 2, pp. 2143. Link . To choose the exact model, the keyword InternalIteration is set to VEM(d), VEM(f), AEM(d), or AEM(f). In contrast to EI-SS-PCM, the II-SS-PCM approach automatically begins with a setup calculation to produce the initial excited state reaction field for the iterations, which then cannot be restarted. To still allow besides the automatic also for manual state following, a specific sequence of states can be listed by appending the chosen method in InternalIteration with -state. The sequence is terminated by a zero, after which state-following is re-engaged. For II-SS-PCM, convergence is judged on the reference state energy and the surface charge vector.

A nonequilibrium II-SS-PCM or VEM calculation corresponds to an iterative version of nonequilibrium ptSS-PCM for vertical excitation energies. Here, also the response of the density to the fast excited state reaction field is included. Hence, the VEM result for the converged reference state (indicated by “EqS-reference” in the output) corresponds to the vertical excitation energy, while the other states have no physical meaning.

Equilibrium II-SS-PCM or AEM, on the other hand, provides the excited reference state energy and transition energies to other excited states. However, emission energies from the reference state to the ground state are adiabatic because the ground state orbitals are not affected by the excited state reaction field. To obtain vertical emission energies, a further fRF ground state calculation has to be performed by setting RF_ptSS_Save = true and loading the reaction field in a consecutive job by setting RF_ptSS_Read = true. See Section 7.8.6 for further information.