Sb-based interband cascade lasers to cover the 3–5 μm spectral window

2011 IEEE Photonics Society Summer Topical Meeting Series Pub Date : 2011-07-18 DOI:10.1109/PHOSST.2011.6000040

C. Canedy, I. Vurgaftman, W. Bewley, C. Kim, M. Kim, C. Merritt, J. Abell, J. Meyer

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Abstract

Semiconductor laser sources for the critical 3–5 um spectral range are evolving and improving rapidly, with significant advancements reported within the last year for three fundamentally different approaches: the intersubband quantum cascade laser (QCL),¹ the type-I quantum well (QW) diode laser,² and the interband cascade laser (ICL).³ Of these three, the most promising candidate to cover the entire wavelength range is the antimonide-based type-II ICL as designed and grown at the Naval Research Laboratory (NRL). Broad area devices have already demonstrated threshold power densities (Pth = current density × voltage) which will enable room temperature (RT) continuous-wave (CW) operation from 2.9 out to 4.6 μm (Fig. 1). The ICL architecture appears uniquely poised not only to offer complete spectral coverage (3–5 μm) but also to operate with low power dissipation. Some of the most recent ICLs display Pth < 0.4 kW/cm² at 300 K (λ ∼ 3.6–4.0 μm), which is more than 20 times lower than the best Pth reported to date for QCLs operating at the same temperature. For this reason, the ICL approach is favored for applications demanding low power and excess heat dissipation, e.g., for long battery lifetimes in the field.

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基于sb的带间级联激光器覆盖3-5 μm光谱窗

关键3-5微米光谱范围的半导体激光源正在迅速发展和改进，去年有三种根本不同的方法取得了重大进展:子带间量子级联激光器(QCL)，1型量子阱(QW)二极管激光器，2和带间级联激光器(ICL)在这三种中，最有希望覆盖整个波长范围的是由海军研究实验室(NRL)设计和培养的基于锑的ii型ICL。广域器件已经证明了阈值功率密度(Pth =电流密度×电压)，这将使室温(RT)连续波(CW)工作范围从2.9 μm到4.6 μm(图1)。ICL架构不仅可以提供完整的频谱覆盖(3-5 μm)，而且可以以低功耗工作。一些最新的icl在300 K (λ ~ 3.6-4.0 μm)下显示的Pth < 0.4 kW/cm2，比迄今为止报道的在相同温度下工作的qcl的最佳Pth低20多倍。因此，ICL方法适用于要求低功耗和过度散热的应用，例如，在现场使用较长的电池寿命。

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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2011 IEEE Photonics Society Summer Topical Meeting Series

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