Development of China's atmospheric environment monitoring satellite CO2 IPDA lidar retrieval algorithm based on airborne campaigns

IF 11.1 1区地球科学 Q1 ENVIRONMENTAL SCIENCES

Remote Sensing of Environment Pub Date : 2024-10-21 DOI:10.1016/j.rse.2024.114473

Shuaibo Wang , Chonghui Cheng , Sijie Chen , Jiqiao Liu , Xingying Zhang , Lingbing Bu , Jingxin Zhang , Kai Zhang , Jiesong Deng , Wentao Xu , Weibiao Chen , Dong Liu

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引用次数: 0

Abstract

China successfully launched the Atmospheric Environment Monitoring Satellite (AEMS) equipped with an Atmospheric Carbon Dioxide Lidar (ACDL) on April 16, 2022, which is the world's first satellite based on Integrated Path Differential Absorption (IPDA) technique to detect the atmospheric CO₂ column-weighted dry-air mixing ratio (XCO₂). In order to accurately and quickly process the AEMS measurements, we proposed a systematic retrieval algorithm for the AEMS ACDL and conducted two airborne campaigns to validate its performance. The first airborne campaign was conducted in the land-sea interface region of northeast China in 2019. The CO₂ retrieval algorithm distinguished significant horizontal XCO₂ gradients over different underlying surfaces and obtained an apparent XCO₂ enhancement of 8–18 ppm between the urban and forests. The CO₂ retrievals not only demonstrated the excellent detection capability of the ACDL for carbon sources and sinks, but also proved the feasibility of the retrieval algorithm in complex terrain and variable atmospheric conditions. The second airborne experiment was conducted in 2021 in the interior desert region of China, which is an excellent flight field to explore the accuracy and precision limits of the retrieval algorithm. We validated the XCO₂ retrievals with the airborne in-situ CO₂ profiles and demonstrated that the XCO₂ accuracy and precision were 0.29 ppm and 0.63 ppm with 1.5-km averages over the desert surface, indicating the accuracy of the retrieval algorithm. The hard target elevation (HTE) retrieval validation results indicate that the IPDA lidar ranging precision is 0.69 m and 6.29 m for the ocean and land surface, respectively. In addition, further analysis combined with the space-borne IPDA lidar simulator showed high consistency in CO₂ precision between airborne measurements and simulation results in East Asia, demonstrating the robustness of the retrieval algorithm at continental scales.

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基于机载活动的中国大气环境监测卫星 CO2 IPDA 激光雷达检索算法的开发

中国于2022年4月16日成功发射了配备大气二氧化碳激光雷达（ACDL）的大气环境监测卫星（AEMS），这是世界上第一颗基于集成路径差分吸收（IPDA）技术探测大气二氧化碳柱加权干气混合比（XCO2）的卫星。为了准确、快速地处理 AEMS 测量数据，我们提出了一种 AEMS ACDL 系统检索算法，并进行了两次机载试验来验证其性能。第一次机载试验于 2019 年在中国东北海陆交界地区进行。二氧化碳检索算法区分了不同底层表面上显著的水平 XCO2 梯度，并在城市和森林之间获得了 8-18 ppm 的 XCO2 表观增强。二氧化碳检索结果不仅证明了ACDL对碳源和碳汇的卓越探测能力，也证明了该检索算法在复杂地形和多变大气条件下的可行性。第二次机载实验于 2021 年在中国内陆沙漠地区进行，该地区是探索检索算法准确度和精度极限的绝佳飞行区域。我们利用机载原位二氧化碳剖面图验证了 XCO2 的检索结果，结果表明，在沙漠表面 1.5 公里的平均范围内，XCO2 的精度和准确度分别为 0.29 ppm 和 0.63 ppm，表明了检索算法的准确性。硬目标高程（HTE）检索验证结果表明，IPDA 激光雷达在海洋和陆地表面的测距精度分别为 0.69 米和 6.29 米。此外，结合空间 IPDA 激光雷达模拟器进行的进一步分析表明，东亚地区的机载测量和模拟结果在二氧化碳精度方面具有很高的一致性，证明了该检索算法在大陆尺度上的稳健性。

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来源期刊

Remote Sensing of Environment 环境科学-成像科学与照相技术

CiteScore

25.10

自引率

8.90%

发文量

455

审稿时长

53 days

期刊介绍： Remote Sensing of Environment (RSE) serves the Earth observation community by disseminating results on the theory, science, applications, and technology that contribute to advancing the field of remote sensing. With a thoroughly interdisciplinary approach, RSE encompasses terrestrial, oceanic, and atmospheric sensing. The journal emphasizes biophysical and quantitative approaches to remote sensing at local to global scales, covering a diverse range of applications and techniques. RSE serves as a vital platform for the exchange of knowledge and advancements in the dynamic field of remote sensing.