AI Article Synopsis
- * Sensitized erbium (Er) in organic materials shows promise for achieving efficient 1.5-µm luminescence, but improvements in electroluminescence intensity are necessary for practical applications.
- * A newly developed OLED uses a traditional organic phosphorescent sensitizer to enhance Er luminescence significantly, achieving an impressive average lifetime of ~0.86 ms and increasing luminescence intensity by 1600 times, making bright 1.5-µm OLEDs possible.
Article Abstract
Advanced 1.5-µm emitting materials that can be used to fabricate electrically driven light-emitting devices have the potential for developing cost-effective light sources for integrated silicon photonics. Sensitized erbium (Er) in organic materials can give bright 1.5-µm luminescence and provide a route for realizing 1.5-µm organic light emitting diodes (OLEDs). However, the Er electroluminescence (EL) intensity needs to be further improved for device applications. Herein, an efficient 1.5-µm OLED made from a sensitized organic Er co-doped system is realized, where a "traditional" organic phosphorescent molecule with minimal triplet-triplet annihilation is used as a chromophore sensitizer. The chromophore provides efficient sensitization to a co-doped organic Er complex with a perfluorinated-ligand shell. The large volume can protect the Er 1.5-µm luminescence from vibrational quenching. The average lifetime of the sensitized Er 1.5-µm luminescence reaches ~0.86 ms, with a lifetime component of 2.65 ms, which is by far the longest Er lifetime in a hydrogen-abundant organic environment and can even compete with that obtained in the fully fluorinated organic Er system. The optimal sensitization enhances the Er luminescence by a factor of 1600 even with a high concentration of the phosphorescent molecule, and bright 1.5-µm OLEDs are obtained.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7054420 | PMC |
| http://dx.doi.org/10.1038/s41377-020-0266-3 | DOI Listing |
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