Universal Electroluminescence at Voltages below the Energy Gap in Organic Light-Emitting Diodes

In organic light-emitting diodes (OLEDs), it is typically assumed that a voltage equal to or higher than the energy gap of the emitters is required to observe electroluminescence (EL). However, EL at subgap voltages is observed and proposed to originate from up-conversion processes, such as fusion of low-energy triplet excitons. Here, it is demonstrated that EL at subgap voltages in OLEDs is universally present. By using emitters with negligible energy splitting between the singlet and triplet state, the need for incorporating low-energy triplet excitons is ruled out. The origin of EL at voltages below the energy gap is the recombination of diffused and thermally generated charge carriers, universally present in light-emitting diodes at nonzero temperatures, theoretically permitting electrical-to-optical power-conversion efficiencies exceeding unity.

Automated summary

The study demonstrates the presence of electroluminescence at subgap voltages in organic light-emitting diodes, originating from the recombination of charge carriers. This phenomenon is universally present in light-emitting diodes and theoretically allows for electrical-to-optical power-conversion efficiencies exceeding unity.