losses due to a suitable Δ E T (≤0.3 eV) between the respective host and guest. Employing as few as possible components in the emitting system of WOLEDs is a means to reduce the energy losses through the simplifi ed exciton-formation and energy-transfer processes. For achieving this, appropriate multifunctional emitter molecules are needed combined with a smart device design strategy.A few effi cient phosphorescent OLEDs (PhOLEDs) have been reported based on phosphorescent hosts. [ 7a,d ] These nofl uorescent-host emitting systems are promising to simplify/optimize the electrophosphorescent process. [ 7 ] However, until now, integrating such an advanced doping model into the construction of the WOLEDs has not yet been achieved. In this work, three emitting complexes originating from our group: bis(2-(2-hydroxyphenyl)-pyridine)beryllium (Bepp 2 , λ max ≈ 450 nm), [ 8 ] bis(4,6-di-fl uorophenyl)pyridinato-N , C 2′ iridium (III) N , N ′-diisopropyl-carbazol-9-yl-amidine (FPPCA, λ max ≈ 500 nm), and bis (7,8-benzoquinolinato)[ 9 ] which could provide essential colors of blue (B), green (G), and orangered (OR), respectively, for white light, were well organized for realizing a simplifi ed WOLED composed of two adjacent G-OR (FPPCA:BZQPG) and B-G (Bepp 2 :FPPCA) emitting layers (EMLs). In this strategy, phosphorescent (P) molecule FPPCA was distributed through both EMLs and showed an unprecedented multifunctional property by playing four key roles: (i) the charge-transporting host, (ii) the green emitting host, (iii) the sensitizer for the dopant P molecule BZQPG in the G-OR layer, and (iv) the green dopant emitter in the B-G layer. This new method endowed the device with the advantage of a reduced number of constituent components and EMLs, which allows for a simplifi ed fabrication processes and effectively reduces structural heterogeneity. Furthermore, careful manipulation for the well-matched FPPCA:BZQPG combination utilizes all the electrically generated excitons in the phosphor-phosphor type (PPT) G-OR layer, where the bipolar character of FPPCA results in a wide emission zone to enhance carrier and exciton utilization, thereby dominating the high electrophosphorescent effi ciency. Meanwhile, the fl uorescent (F) molecule Bepp 2 is used to generate blue singlet emission in the B-G layer and served as a host for sensitizing green emission, thereby achieving the broad white EL spectrum. An optimal management of B-G and G-OR layers aiming at balanced charge injection together with simultaneous effi cient charge/exciton confi nement, ensured this three-color device possesses stable and high EL performance White organic light-emitting diodes (OLEDs) are a very promising technology for next-generation solid-state lighting. [ 1 ] High-quality illumination sources require white OLEDs (WOLEDs) with a high color-rendering index (CRI) of >80. [ 1c ] Although some two-color WOLEDs produced by an orange or yellow emitter complemented with a blue emitter, exhibit impressive electroluminescence (EL) effi ciency, they ha...
