Electroluminescence from single monolayers of nanocrystals in molecular organic devices

Abstract

The integration of organic and inorganic materials at the nanometre scale into hybrid optoelectronic structures enables active devices^1,2,3 that combine the diversity of organic materials with the high-performance electronic and optical properties of inorganic nanocrystals⁴. The optimization of such hybrid devices ultimately depends upon the precise positioning of the functionally distinct materials. Previous studies^5,6 have already emphasized that this is a challenge, owing to the lack of well-developed nanometre-scale fabrication techniques. Here we demonstrate a hybrid light-emitting diode (LED) that combines the ease of processability of organic materials with the narrow-band, efficient luminescence of colloidal quantum dots⁷ (QDs). To isolate the luminescence processes from charge conduction, we fabricate a quantum-dot LED (QD-LED) that contains only a single monolayer of QDs, sandwiched between two organic thin films. This is achieved by a method that uses material phase segregation between the QD aliphatic capping groups and the aromatic organic materials. In our devices, where QDs function exclusively as lumophores, we observe a 25-fold improvement in luminescence efficiency (1.6 cd A^-1 at 2,000 cd m^-2) over the best previous QD-LED results⁵. The reproducibility and precision of our phase-segregation approach suggests that this technique could be widely applicable to the fabrication of other hybrid organic/inorganic devices.