Abstract
Tuneable microlasers that span the full visible spectrum, particularly red, green, and blue (RGB) colors, are of crucial importance for various optical devices. However, RGB microlasers usually operate in multimode because the mode selection strategy cannot be applied to the entire visible spectrum simultaneously, which has severely restricted their applications in on-chip optical processing and communication. Here, an approach for the generation of tuneable multicolor single-mode lasers in heterogeneously coupled microresonators composed of distinct spherical microcavities is proposed. With each microcavity serving as both a whispering-gallery-mode (WGM) resonator and a modulator for the other microcavities, a single-mode laser has been achieved. The colors of the single-mode lasers can be freely designed by changing the optical gain in coupled cavities owing to the flexibility of the organic materials. Benefiting from the excellent compatibility, distinct color-emissive microspheres can be integrated to form a heterogeneously coupled system, where tuneable RGB single-mode lasing is realized owing to the capability for optical coupling between multiple resonators. Our findings provide a comprehensive understanding of the lasing modulation that might lead to innovation in structure designs for photonic integration.
Highlights
Tuneable microlasers that span the full visible spectrum are essential building blocks for lighting technology, full color laser display, and sensing[1,2,3,4]
Due to the inhomogeneous gain saturation introduced by spatial hole burning, most wavelength-tuneable microlasers are subject to operation in multimode, which will lead to temporal fluctuations and false signaling[5,6,7,8]
Expanding the free spectral range (FSR) by reducing the cavity size is effective for multicolor singlemode microlasers[16], which can be applied to different wavelengths simultaneously but may increase the threshold[17]
Summary
Tuneable microlasers that span the full visible spectrum are essential building blocks for lighting technology, full color laser display, and sensing[1,2,3,4]. Due to the inhomogeneous gain saturation introduced by spatial hole burning, most wavelength-tuneable microlasers are subject to operation in multimode, which will lead to temporal fluctuations and false signaling[5,6,7,8]. RGB microlasers were achieved mainly by integrating different gain media into single photonic devices[11,12,13,14,15], which usually suffer from operating in multimode. Expanding the free spectral range (FSR) by reducing the cavity size is effective for multicolor singlemode microlasers[16], which can be applied to different wavelengths simultaneously but may increase the threshold[17]. With one cavity applied as a modulator of the other, could enable the expansion of the FSR while avoiding an obvious increase in threshold and
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