GaN-based distributed feedback laser diodes for optical communications

Fourth International Conference on Applications of Optics and Photonics Pub Date : 2019-10-03 DOI:10.1117/12.2527074

S. Gwyn, S. Watson, S. Viola, G. Giuliano, T. Slight, S. Stanczyk, S. Grzanka, A. Yadav, K. Docherty, E. Rafailov, P. Perlin, S. Najda, M. Leszczynski, A. Kelly

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引用次数: 4

Abstract

Over the past 20 years, research into Gallium Nitride (GaN) has evolved from LED lighting to Laser Diodes (LDs), with applications ranging from quantum to medical and into communications. Previously, off-the-shelf GaN LDs have been reported with a view on free space and underwater communications. However, there are applications where the ability to select a single emitted wavelength is highly desirable, namely in atomic clocks or in filtered free-space communications systems. To accomplish this, Distributed Feedback (DFB) geometries are utilised. Due to the complexity of overgrowth steps for buried gratings in III-Nitride material systems, GaN DFBs have a grating etched into the sidewall to ensure single mode operation, with wavelengths ranging from 405nm to 435nm achieved. The main motivation in developing these devices is for the cooling of strontium ions (Sr+ ) in atomic clock applications, but their feasibility for optical communications have also been investigated. Data transmission rates exceeding 1 Gbit/s have been observed in unfiltered systems, and work is currently ongoing to examine their viability for filtered communications. Ultimately, transmission through Wavelength Division Multiplexing (WDM) or Orthogonal Frequency Division Multiplexing (OFDM) is desired, to ensure that data is communicated more coherently and efficiently. We present results on the characterisation of GaN DFBs, and demonstrate their capability for use in filtered optical communications systems.

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光通信用氮化镓分布式反馈激光二极管

在过去的20年里，对氮化镓(GaN)的研究已经从LED照明发展到激光二极管(ld)，应用范围从量子到医疗再到通信。以前，现成的GaN ld已经被报道用于自由空间和水下通信。然而，在某些应用中，选择单一发射波长的能力是非常可取的，即在原子钟或过滤的自由空间通信系统中。为了实现这一点，使用了分布式反馈(DFB)几何图形。由于iii -氮化物材料系统中埋地光栅的过度生长步骤的复杂性，GaN dfb在侧壁上蚀刻了一个光栅，以确保单模工作，波长范围从405nm到435nm。开发这些器件的主要动机是为了在原子钟应用中冷却锶离子(Sr+)，但它们在光通信方面的可行性也得到了研究。在未过滤的系统中已经观察到超过1 Gbit/s的数据传输速率，目前正在研究它们在过滤通信中的可行性。最终，希望通过波分复用(WDM)或正交频分复用(OFDM)传输，以确保数据通信更加连贯和有效。我们介绍了GaN dfb的表征结果，并展示了它们在滤波光通信系统中的使用能力。

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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Fourth International Conference on Applications of Optics and Photonics

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