posted on 2022-12-14, 14:34authored byD. Chaudhuri, C. H. Patterson
Design concepts for organic light emitting diode (OLED)
emitters,
which exhibit thermally activated delayed fluorescence (TADF) and
thereby achieve quantum yields exceeding 25%, depend on singlet–triplet
splitting energies of order kT to allow reverse intersystem
crossing at ambient temperatures. Simulation methods for these systems
must be able to treat relatively large organic molecules, as well
as predict their excited state energies, transition energies, singlet–triplet
splittings, and absorption and emission cross sections with reasonable
accuracy, in order to prove useful in the design process. Here we
compare predictions of TDDFT with M06-2X and ωB97X-D exchange-correlation
functionals and a GoWo@HF/BSE method for these quantities
in the well-studied DPTZ-DBTO2 TADF emitter molecule. Geometry optimization
is performed for ground state (GS) and lowest donor–acceptor
charge transfer (CT) state for each functional. Optical absorption
and emission cross sections and energies are calculated at these geometries.
Relaxation energies are on the order of 0.5 eV, and the importance
of obtaining excited state equilibrium geometries in predicting delayed
fluorescence is demonstrated. There are clear trends in predictions
of GoWo@HF/BSE, and TDDFT/ωB97X-D and
M06-2X methods in which the former method favors local exciton (LE)
states while the latter favors DA CT states and ωB97X-D makes
intermediate predictions. GoWo@HF/BSE suffers
from triplet instability for LE states but not CT states relevant
for TADF. Shifts in HOMO and LUMO levels on adding a conductor-like
polarizable continuum model dielectric background are used to estimate
changes in excitation energies on going from the gas phase to a solvated
molecule.