Accurate Spectral Properties within Double-Hybrid
Density Functional Theory: A Spin-Scaled Range-Separated Second-Order
Algebraic-Diagrammatic Construction-Based Approach
posted on 2022-01-13, 16:29authored byDávid Mester, Mihály Kállay
Our second-order
algebraic-diagrammatic construction [ADC(2)]-based
double-hybrid (DH) ansatz (J. Chem. Theory Comput.2019, 15, 4440. DOI: 10.1021/acs.jctc.9b00391)
is combined with range-separation techniques. In the present scheme,
both the exchange and the correlation contributions are range-separated,
while spin-scaling approaches are also applied. The new methods are
thoroughly tested for the most popular benchmark sets including 250
singlet and 156 triplet excitations, as well as 80 oscillator strengths.
It is demonstrated that the range separation for the correlation contributions
is highly recommended for both the genuine and the ADC(2)-based DH
approaches. Our results show that the latter scheme slightly but consistently
outperforms the former one for single excitation dominated transitions.
Furthermore, states with larger fractions of double excitations are
assessed as well, and challenging charge-transfer excitations are
also discussed, where the recently proposed spin-scaled long-range
corrected DHs fail. The suggested iterative fourth-power scaling RS-PBE-P86/SOS-ADC(2)
method, using only three adjustable parameters, provides the most
robust and accurate excitation energies within the DH theory. In addition,
the relative error of the oscillator strengths is reduced by 65% compared
to the best genuine DH functionals.