Fig. 4 Perovskite-infused nanoporous thin films for LEDs.

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Presentation transcript:

Fig. 4 Perovskite-infused nanoporous thin films for LEDs. Perovskite-infused nanoporous thin films for LEDs. (A) Schematic of npPeLEDs. Devices are fabricated on glass/FTO by anodizing a titanium/aluminum bilayer. This electrochemical procedure produces npAAO with compact TiO2 below. Precursor solution infused to the top of the pores yields conducting and electroluminescent nanocrystalline perovskite domains. A polymeric HTL and hole-injecting contact of MoOx/Ag complete the device stack. (B) SEM of anodized Ti/Al, showing the npAAO layer with pores of ~6-nm diameter on top of the scale-like Ti/TiO2 domains below. (C) PL micrograph image taken of a Ti/npAAO layer infused with CsPbBr3, evidencing uniform light emission across large areas of the sample. Excitation filter, 465 to 495 nm; barrier filter, 515 to 555 nm. (D) EL of an ncMAPbI3 diode, (filled curve) centered around 731 nm, with bulk PL emission (dashed line) and PL of the ncMAPbI3 diode (solid curve) plotted for comparison. (E) EL (filled curve) of an ncCsPbBr3 diode with PL emission of the bulk (dashed line) and the ncCsPbBr3 diode is shown (solid line). Cyan-green narrowband EL peaking at 518 nm is observed. (F) J-V characteristic of an ncCsPbBr3 diode (black trace) plotted together with luminance (cyan). Devices turn on at ~2.5 V with a luminance of ~330 cd m−2 at 5 V. (G) Photograph of a CsPbBr3 diode while operating at 4 V, displaying cyan-green EL over the entire area of the pixel (15 mm2). Stepan Demchyshyn et al. Sci Adv 2017;3:e1700738 Copyright © 2017 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).