Multicolor single-mode polarized microlasers containing an output range from visible light to the near-infrared have significant applications in photonic integration and multimodal chemical sensing or imaging applications. However, such devices are very difficult to realize in practice. In a new report, Huajun He and a research team in physics, materials science and chemistry in Singapore, China and the U.S., developed a single crystal with multiple segments to generate controlled, single-mode, near-infrared (NIR) lasing. Multiple segments of the single crystal were based on a metal organic framework (MOF) hybridized with dye molecules suited for green, red and near-infrared lasing as computationally simulated. The segmented assembly of different dye molecules in the microcrystal caused it to act as a shortened resonator to achieve dynamic, multicolor single-mode lasing with a low three-color-lasing threshold (red, green and NIR). The findings will open a new route to explore single-mode, micro/nanolasers constructed with MOF engineering for biophotonic applications. The work is now published on Nature Light: Science & Applications.
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Source: Phys.org