We study the electronic coupling matrix element for triplet excitation energy-transfer processes with a number of different computational methods. For the first time, constrained density functional theory (CDFT) is applied to the problem of energy transfer, and results are compared with direct coupling calculations of broken symmetry and fragment densities, as well as the splitting method. A naïve calculation of the electronic coupling using diabatic and adiabatic energy differences is shown to yield erroneous results due to the fractional spin error present in both Hartree−Fock and commonly used DFT exchange−correlation functionals. Some potential issues concerning the splitting method with triplet references within Hartree−Fock and DFT a...
The accurate prediction of singlet and triplet excitation energies is an area of intense research of...
International audienceThe accurate prediction of singlet and triplet excitation energies is an area ...
The Tamm–Dancoff approximation (TDA) can be applied to the computation of excitation energies using ...
A simplified approach for computing the electronic coupling of nonradiative excitation-energy transf...
The electronic coupling for triplet energy transfer is calculated by time-dependent density function...
We consider necessary conditions for the one-body reduced density matrix (1RDM) to correspond to a t...
In this study, the use of self-consistent field quasi-diabats is investigated for calculation of tri...
We report a novel scheme for computing electronic excitation energies within the framework of densit...
\u3cp\u3eA general approach to determine orientation and distance-dependent effective intermolecular...
Kohn–Sham density functional theory has been tremendously successful in chemistry and physics. Yet, ...
Our work reveals a high dependence on charge-transfer (CT) amounts for the optimal Hartree–Fock perc...
Quantum-mechanical methods that are both computationally fast and accurate are not yet available for...
We applied renormalized singles (RS) in the multireference density functional theory (DFT) to calcul...
Density functional theory (DFT) is the most widely used quantum chemistry method. This dissertation ...
Electronic coupling matrix elements are important to the theoretical description of electron transfe...
The accurate prediction of singlet and triplet excitation energies is an area of intense research of...
International audienceThe accurate prediction of singlet and triplet excitation energies is an area ...
The Tamm–Dancoff approximation (TDA) can be applied to the computation of excitation energies using ...
A simplified approach for computing the electronic coupling of nonradiative excitation-energy transf...
The electronic coupling for triplet energy transfer is calculated by time-dependent density function...
We consider necessary conditions for the one-body reduced density matrix (1RDM) to correspond to a t...
In this study, the use of self-consistent field quasi-diabats is investigated for calculation of tri...
We report a novel scheme for computing electronic excitation energies within the framework of densit...
\u3cp\u3eA general approach to determine orientation and distance-dependent effective intermolecular...
Kohn–Sham density functional theory has been tremendously successful in chemistry and physics. Yet, ...
Our work reveals a high dependence on charge-transfer (CT) amounts for the optimal Hartree–Fock perc...
Quantum-mechanical methods that are both computationally fast and accurate are not yet available for...
We applied renormalized singles (RS) in the multireference density functional theory (DFT) to calcul...
Density functional theory (DFT) is the most widely used quantum chemistry method. This dissertation ...
Electronic coupling matrix elements are important to the theoretical description of electron transfe...
The accurate prediction of singlet and triplet excitation energies is an area of intense research of...
International audienceThe accurate prediction of singlet and triplet excitation energies is an area ...
The Tamm–Dancoff approximation (TDA) can be applied to the computation of excitation energies using ...