氧a波段吸收光谱与太阳光子计数和铌酸锂纳米光子电路

Frontiers in Remote Sensing Pub Date : 2022-11-18 DOI:10.3389/frsen.2022.1064244

Jiuyi Zhang, Y. Sua, Yongxiang Hu, Jeevanandha Ramanathan, Yu-ping Huang

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引用次数: 0

摘要

氧a波段测量可以提供有关云顶高度、云物理和光学厚度以及地面大气压力的重要信息。到目前为止，O2 a波段的测量通常是用光谱分辨率为40pm(如OCO-2卫星)或更低分辨率的光谱仪进行的。本文报道了一种利用集成光子电路和太阳光子计数技术在O2 - a波段具有更高光谱分辨率的新立方体卫星测量概念。设计、制造了一种集成微环滤波器(MRR)芯片，该芯片具有10pm谐振线宽，消光比为25db或更高，并用于精确测量大气氧a波段吸收线形状约770 nm。通过太阳光子计数和使用由集成的、快速扫描的铌酸锂绝缘体(LNOI)上的MRR制成的窄带滤波器，我们展示了对O2 a波段吸收光谱的高分辨率测量，与HITRAN数据库显示出良好的一致性。

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Oxygen A-band absorption spectroscopy with solar photon counting and lithium niobate nanophotonic circuits

Oxygen A-band measurements can provide important information about cloud top height, cloud physical and optical thickness, and surface atmospheric pressure. So far, O2 A-band measurements are typically made with spectrometers at a spectral resolution of 40 p.m. (such as in the OCO-2 satellite) or a coarser resolution. This paper reports a new CubeSat measurement concept with higher spectral resolution over the O2 A-band using integrated photonic circuits and solar photon counting techniques. An integrated Micro-ring filter (MRR) chip with 10 p.m. resonant linewidth with an extinction ratio of 25 dB or higher is designed, fabricated, and used for precise measurements of the atmospheric oxygen A-band absorption line-shapes around 770 nm. With solar-photon counting and using a narrow-band filter made of an integrated, fast-swept MRR on lithium niobate on insulator (LNOI), we have demonstrated a high-resolution measurement of the O2 A-band absorption spectrum, exhibiting good agreement with the HITRAN database.

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Frontiers in Remote Sensing

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