Abstract
Following the very promising results obtained by the solar cell community, metal halide perovskite materials are increasingly attracting the attention of other optoelectronics researchers, especially for light emission applications. Lasing with both engineered and self-assembled resonator structures, such as microcrystal networks, has now been successfully observed, with the low cost and the simple solution-based process being a particular attraction. The ultimate in simplicity, however, would be to observe lasing from a continuous thin film, which has not been reported yet. Here, we show random lasing action from such a simple perovskite layer. Our lasers work at room temperature; they are deposited on unpatterned glass substrates and they exhibit a minimum threshold value of 10 µJ/cm2. By carefully controlling the solution processing conditions, we can determine whether random lasing occurs or not, using identical precursors. A rather special feature is that some of the films exhibit single and dual mode lasing action, which is rarely observed in random lasers. Our work fully exploits the simplicity of the solution-based process and thereby adds an important capability into the emerging field of perovskite-based light emitters.
Highlights
The family of metal halide perovskite materials has recently caused a step-change in the photovoltaics community based on their efficient absorption properties and the high opencircuit voltages they provide
Motivated by these excellent optoelectronic properties, researchers have in turn examined their light emission properties and have reported LED [1,2] and lasing operation [3] over a broad wavelength range
The ultimate in simplicity for a laser device, naturally, is a laser that creates its own feedback through scattering in the gain medium, i.e. a random laser
Summary
The family of metal halide perovskite materials has recently caused a step-change in the photovoltaics community based on their efficient absorption properties and the high opencircuit voltages they provide. Motivated by these excellent optoelectronic properties, researchers have in turn examined their light emission properties and have reported LED [1,2] and lasing operation [3] over a broad wavelength range. The perovskite material family provides attractive optoelectronic properties, including strong photopumped light emission [10,11], bright electroluminescence [12,13], and the observation of optically pumped lasing, along with wide wavelength tuneability [1,14,15]
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