核壳聚苯乙烯微球的固体激光制冷

Rachel E. Gariepy, Xiaojing Xia, R. G. Felsted, Ayelet Teitelbom, E. Chan, P. Pauzauskie
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引用次数: 0

摘要

基于窃窃廊模式(WGMs)与上转换过程耦合的微激光设计已经被证明具有许多有价值的品质,如高Q因子和低激光阈值。这些微激光器设计仍然面临的一个障碍是增益介质的光热加热带来的挑战,这可以通过设计辐射平衡微激光器来解决。本文在直径为5 μm的聚苯乙烯微球上制备了一层掺Yb3+的NaYF4 UCNPs,以测试UCNPs的抗stokes冷却性能是否能在激光照射下冷却微谐振器及其环境。我们通过校准的平均荧光光谱发现,UCNPs可以将其局部环境冷却高达23°C,并显着降低微谐振器周围水环境的加热,这表明有希望包含在辐射平衡微激光器的设计中。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Solid-state laser refrigeration of core-shell polystyrene microspheres
Microlaser designs based on the coupling of whispering gallery modes (WGMs) with the upconversion processes which take place within lanthanide-doped nanoparticles (UCNPs) have been demonstrated and shown to have many valuable qualities, such as high Q factors and low lasing thresholds. One obstacle that these microlaser designs still face is the challenges caused by photothermal heating of the gain medium, which could be solved through the design of a radiation balanced microlaser. In this work, WGM microresonators composed of 5 μm diameter polystyrene spheres are fabricated with a layer of Yb3+-doped NaYF4 UCNPs in order to test if the anti-Stokes cooling properties of the UCNPs can cool the microresonator and its environment under laser irradiation. We find via calibrated mean fluorescence spectroscopy that the UCNPs can cool their local environment by as much as 23 °C and significantly reduce the heating of the aqueous environment surrounding the microresonator, showing promise for inclusion in a design for a radiation balanced microlaser.
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