光子学
激光器
光电子学
生物光子学
材料科学
Q开关
硅光子学
能量(信号处理)
光学
物理
量子力学
作者
Neetesh Singh,Jan Lorenzen,Milan Sinobad,Kai Wang,Andreas C. Liapis,Henry C. Frankis,Stefanie Haugg,Henry Francis,José Carreira,Michael Geiselmann,Mahmoud A. Gaafar,Tobias Herr,Jonathan D. B. Bradley,Zhipei Sun,Sonia M. García‐Blanco,Franz X. Kärtner
出处
期刊:Nature Photonics
[Nature Portfolio]
日期:2024-02-09
卷期号:18 (5): 485-491
被引量:40
标识
DOI:10.1038/s41566-024-01388-0
摘要
Abstract Chip-scale, high-energy optical pulse generation is becoming increasingly important as integrated optics expands into space and medical applications where miniaturization is needed. Q -switching of the laser cavity was historically the first technique to generate high-energy pulses, and typically such systems are in the realm of large bench-top solid-state lasers and fibre lasers, especially in the long wavelength range >1.8 µm, thanks to their large energy storage capacity. However, in integrated photonics, the very property of tight mode confinement that enables a small form factor becomes an impediment to high-energy applications owing to small optical mode cross-sections. Here we demonstrate a high-energy silicon photonics-based passively Q -switched laser with a compact footprint using a rare-earth gain-based large-mode-area waveguide. We demonstrate high on-chip output pulse energies of >150 nJ and 250 ns pulse duration in a single transverse fundamental mode in the retina-safe spectral region (1.9 µm), with a slope efficiency of ~40% in a footprint of ~9 mm 2 . The high-energy pulse generation demonstrated in this work is comparable to or in many cases exceeds that of Q -switched fibre lasers. This bodes well for field applications in medicine and space.
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