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Ultralow‐Threshold and High‐Quality Whispering‐Gallery‐Mode Lasing from Colloidal Core/Hybrid‐Shell Quantum Wells

Duan, Rui and Zhang, Zitong and Xiao, Lian and Zhao, Xiaoxu and Thung, Yi Tian and Ding, Lu and Liu, Zheng and Yang, Jun and Ta, Van Duong and Sun, Handong (2022) Ultralow‐Threshold and High‐Quality Whispering‐Gallery‐Mode Lasing from Colloidal Core/Hybrid‐Shell Quantum Wells. Advanced Materials. p. 2108884. ISSN 0935-9648

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Abstract

The realization of efficient on-chip microlasers with scalable fabrication, ultralow threshold, and stable single-frequency operation is always desired for a wide range of miniaturized photonic systems. Herein, an effective way to fabricate nanostructures- whispering-gallery-mode (WGM) lasers by drop-casting CdSe/CdS@Cd1−xZnxS core/buffer-shell@graded-shell nanoplatelets (NPLs) dispersion onto silica microspheres is presented. Benefiting from the excellent gain properties from the interface engineered core/hybrid shell NPLs and high-quality factor WGM resonator from excellent optical field confinement, the proposed room-temperature NPLs-WGM microlasers show a record-low lasing threshold of 3.26 µJ cm−2 under nanosecond laser pumping among all colloidal NPLs-based lasing demonstrations. The presence of sharp discrete transverse electric- and magnetic-mode spikes, the inversely proportional dependence of the free spectra range on microsphere sizes and the polarization anisotropy of laser output represent the first direct experimental evidence for NPLs-WGM lasing nature, which is verified theoretically by the computed electric-field distribution inside the microcavity. Remarkably, a stable single-mode lasing output with an ultralow lasing threshold of 3.84 µJ cm−2 is achieved by the Vernier effect through evanescent field coupling. The results highlight the significance of interface engineering on the optimization of gain properties of heterostructured nanomaterials and shed light on developing future miniaturized tunable coherent light sources. © 2022 Wiley-VCH GmbH.

Item Type: Article
Divisions: Faculties > Faculty of Special Equipments
Identification Number: 10.1002/adma.202108884
Uncontrolled Keywords: Cadmium compounds; Electric fields; Evanescent fields; II-VI semiconductors; Microspheres; Optical resonators; Pumping (laser); Quantum well lasers; Semiconductor quantum wells; Whispering gallery modes, Gain properties; High quality; Lasings; Microlaser; Nanoplatelet; On chips; Photonic systems; Quantum-wells; Single frequency operation; Ultra-low threshold, Silica
URI: http://eprints.lqdtu.edu.vn/id/eprint/10305

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