11.7 Frozen-Density Embedding Theory 11.7.1 Introduction 11.7.3 FDE-Man Job Control

11.7.2 FDE-Man

(September 1, 2024)

Several FDET-based methods are available in the FDE-Man module of Q-Chem. The FDE-Man job control is accomplished in two sections, $rem and $fde.

The fragments are specified via the fragment descriptors (see Section 12) in the $molecule section, whereas the first fragment corresponds to the embedded species (A), the second fragment represents the environment (B).

Note: The current implementation allows only for closed shell fragments.

FDE

FDE
       Turns density embedding on.
TYPE:
       BOOLEAN
DEFAULT:
       False
OPTIONS:
       True Perform an FDET calculation. False Don’t perform FDET calculation.
RECOMMENDATION:
       Set the $rem variable FDE to TRUE to start a FDET calculation.

Enabling FDE-Man, the specification of the embedding method and other job control parameters (thresholds, max. iterations etc.) should be set in the $rem section.

METHOD

METHOD
       Determines which FDET-based method should be used for the embedded wavefunction if FDE = TRUE.
TYPE:
       STRING
DEFAULT:
       None
OPTIONS:
       NAME Use METHOD = NAME, where NAME is either HF for Hartree-Fock theory or else one of the DFT methods listed in Section 5.3.5.
RECOMMENDATION:
       None

Other DFT functionals can also be requested with the EXCHANGE and CORRELATION keywords as described in Section 5.4.

Note: The current implementation is restricted to mean-field methods that are solved with the SCFMAN module.

The standard capabilities to use customized basis sets are also possible with the FDE-Man module.

11.7.2.1 FDE-ADC

FDE-ADC ¹⁰⁴⁶ Prager S. et al.
J. Chem. Phys.
(2016), 144, pp. 204103. Link is a density embedding method based on the combination of the Algebraic Diagrammatic Construction scheme for the polarization propagator (ADC, Section 7.11) and Frozen-Density Embedding Theory (FDET). In this particular variant, the subsystem A is represented by a wave function whereas subsystem B is described by a density. The FDE-ADC method uses the linearized FDET approximation. ¹⁴²⁷ Zech A., Aquilante F., Wesolowski T. A.
J. Chem. Phys.
(2015), 143, pp. 164106. Link

Similar to the other methods, the ADC specifications have to be done inside the $rem section, as shown below.

METHOD

METHOD
       Determines which FDET-based method should be used if FDE = TRUE.
TYPE:
       STRING
DEFAULT:
       None
OPTIONS:
       adc(2) Perform an FDE-ADC(2)-s calculation. adc(2)-x Perform an FDE-ADC(2)-x calculation. adc(3) Perform an FDE-ADC(3) calculation (potential constructed with MP(2) density). cvs-adc(2) Perform an FDE-ADC(2)-s calculation of core excitations. cvs-adc(2)-x Perform an FDE-ADC(2)-x calculation of core excitations. cvs-adc(3) Perform an FDE-ADC(3) calculation of core excitations.
RECOMMENDATION:
       None

FDE-ADC also supports the excited state analysis (STATE_ANALYSIS) carried out by the libwfa module.

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11.7.2 FDE-Man

11.7.2.1 FDE-ADC