posted on 2016-06-23, 00:00authored byMay L. Lai, Timothy
Y. S. Tay, Aditya Sadhanala, Siân E. Dutton, Guangru Li, Richard H. Friend, Zhi-Kuang Tan
Infrared
emitters are reasonably rare in solution-processed materials.
Recently, research into hybrid organo-lead halide perovskite, originally
popular in photovoltaics,− has gained traction in light-emitting
diodes (LED) due to their low-cost solution processing and good performance.− The lead-based electroluminescent materials show strong colorful
emission in the visible region, but lack emissive variants further
in the infrared. The concerns with the toxicity of lead may, additionally,
limit their wide-scale applications. Here, we demonstrate tunable
near-infrared electroluminescence from a lead-free organo-tin halide
perovskite, using an ITO/PEDOT:PSS/CH3NH3Sn(Br1–xIx)3/F8/Ca/Ag device architecture. In our tin iodide (CH3NH3SnI3) LEDs, we achieved a 945 nm near-infrared
emission with a radiance of 3.4 W sr–1 m–2 and a maximum external quantum efficiency of 0.72%, comparable with
earlier lead-based devices. Increasing the bromide content in these
tin perovskite devices widens the semiconductor bandgap and leads
to shorter wavelength emissions, tunable down to 667 nm. These near-infrared
LEDs could find useful applications in a range of optical communication,
sensing and medical device applications.