The ALMO-CIS
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and ALMO-CIS+CT
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methods are local
variants of Configuration Interaction Singles (CIS) for excited states, which are
formulated based on the locality of Absolutely Localized Molecular Orbitals (ALMOs).
The ALMO-CIS method shares same spirit with the TDDFT(MI) method
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(Section 12.18), but it was originally designed to calculate a large
number of excited states in atomic/molecular clusters, e.g., the entire band
in helium clusters that contain hundreds of atoms.
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,
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In ALMO-CIS and ALMO-CIS+CT, one solves a truncated non-orthogonal CIS eigenvalue problem:
(12.76) |
The use of ALMOs allows associating each MO
index (, , , or ) to a fragment. In ALMO-CIS, only the CIS amplitudes
corresponding to intrafragment transitions are retained, i.e., if
the occupied orbital and the virtual orbital reside on two different
fragments. The Hamiltonian and overlap matrix are
also truncated, with () and () belonging to the same fragment.
This approximation excludes interfragment charge transfer (CT) excitations
entirely, which sometimes turns out to be insufficiently accurate.
In ALMO-CIS+CT, the CT effect is reintroduced by providing a distance-based cutoff
() so that transitions between neighboring fragments within
a range of are allowed, i.e., () and () that are
on a pair of neighboring fragments are also included in Eq. (12.76).
In both ALMO-CIS and ALMO-CIS+CT, the dimension of the eigenvalue problem scales
linearly with the system size rather than having a quadratic scaling as in standard
CIS. Because of the reduction of matrix size, it is computationally feasible to
explicitly build the Hamiltonian and directly diagonalize it to obtain a full band of
excited states for relatively large systems. The overall scaling of the diagonalization
step in ALMO-CIS/ALMO-CIS+CT is cubic, in contrast to the sixth-order scaling of
standard CIS for full-spectrum calculation. To accelerate the construction of the
CIS Hamiltonian (the matrix in Eq. (12.76)), the
resolution-of-the-identity (RI) technique is employed to evaluate some of the
2-electron terms (see Ref.
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for details).
Besides the full-spectrum calculations described above, use of the Davidson
algorithm is also available for ALMO-CIS and ALMO-CIS+CT, which targets a few
lowest excited states as in standard CIS/TDDFT calculations. This iterative
method, unlike the original full-spectrum version, also supports the ALMO variant
of linear-response TDDFT within the Tame-Dancoff approximation (TDA),
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which is referred to as ALMO-TDA and shares the same working equation
(Eq. 12.76).