Complete polarization of electronic spins in OLEDs (2010.08313v1)

Abstract: At low temperatures and high magnetic fields, electron and hole spins in an organic light-emitting diode (OLED) become polarized so that recombination preferentially forms molecular triplet excited-state species. For low device currents, magnetoelectroluminescence (MEL) perfectly follows Boltzmann activation, implying a virtually complete polarization outcome. As the current increases, the MEL effect is reduced because spin polarization is suppressed by the reduction in carrier residence time within the device. Under these conditions, an additional field-dependent process affecting the spin-dependent recombination emerges, which appears to relate to the build-up of triplet excitons and the interaction with free charge carriers. Suppression of the EL at high fields on its own does not, strictly, prove electronic spin polarization. We therefore probe changes in the spin statistics of recombination directly in a dual singlettriplet emitting OLED, which shows a concomitant rise in phosphorescence intensity as fluorescence is suppressed. Finite spin-orbit coupling in these materials gives rise to a microscopic distribution in effective g factors of electrons and holes, $\Delta g$, i.e. a distribution in Larmor frequencies, leading to singlet-triplet mixing within the electronhole pair as a function of applied field. This $\Delta g$ effect in the pair further suppresses singlet-exciton formation in addition to thermal spin polarization of the individual carriers. Since the $\Delta g$ process involves weakly bound carrier pairs rather than free electrons and holes, in contrast to thermal spin polarization, the effect does not depend significantly on current or temperature.