Low-coherence semiconductor light sources: devices and applications

npj Nanophotonics Pub Date : 2024-06-03 DOI:10.1038/s44310-024-00005-w

Hang Lu, Omar Alkhazragi, Yue Wang, Nawal Almaymoni, Wenbo Yan, Wahyu Hendra Gunawan, Heming Lin, Tae-Yong Park, Tien Khee Ng, Boon S. Ooi

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Abstract

Since the invention of the laser, there have been countless applications that were made possible or improved through exploiting its multitude of unique advantages. Most of these advantages are mainly due to the high degree of coherence of the laser light, which makes it directional and spectrally pure. Nevertheless, many fields require a moderate degree of temporal or spatial coherence, making conventional lasers unsuitable for these applications. This has brought about a great interest in partially coherent light sources, especially those based on semiconductor devices, given their efficiency, compactness, and high-speed operation. Here, we review the development of low-coherence semiconductor light sources, including superluminescent diodes, highly multimode lasers, and random lasers, and the wide range of applications in which they have been deployed. We highlight how each of these applications benefsits from a lower degree of coherence in space and/or time. We then discuss future potential applications that can be enabled using new types of low-coherence light.

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低相干半导体光源：装置与应用

自激光发明以来，无数的应用都是通过利用激光的众多独特优势来实现或改进的。其中大部分优势主要归功于激光的高度相干性，这使得激光具有方向性和光谱纯净度。然而，许多领域需要适度的时间或空间相干性，因此传统激光器并不适合这些应用。这引起了人们对部分相干光源的极大兴趣，特别是那些基于半导体器件的光源，因为它们效率高、结构紧凑、运行速度快。在此，我们回顾了低相干半导体光源的发展，包括超发光二极管、高度多模激光器和随机激光器，以及它们的广泛应用。我们将重点介绍每种应用如何从空间和/或时间的低相干性中获益。然后，我们将讨论使用新型低相干性光的未来潜在应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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npj Nanophotonics

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