Cloud top heights and aerosol layer properties from EarthCARE lidar observations: the A-CTH and A-ALD products

IF 3.2 3区地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES

Atmospheric Measurement Techniques Pub Date : 2023-09-07 DOI:10.5194/amt-16-4031-2023

U. Wandinger, M. Haarig, H. Baars, D. Donovan, Gerd-Jan van Zadelhoff

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引用次数: 6

Abstract

Abstract. The high-spectral-resolution Atmospheric Lidar (ATLID) on the Earth Cloud, Aerosol and Radiation Explorer (EarthCARE) provides vertically resolved information on aerosols and clouds with unprecedented accuracy. Together with the Cloud Profiling Radar (CPR), the Multi-Spectral Imager (MSI), and the Broad-Band Radiometer (BBR) on the same platform, it allows for a new synergistic view on atmospheric processes related to the interaction of aerosols, clouds, precipitation, and radiation at the global scale. This paper describes the algorithms for the determination of cloud top height and aerosol layer information from ATLID Level 1b (L1b) and Level 2a (L2a) input data. The ATLID L2a Cloud Top Height (A-CTH) and Aerosol Layer Descriptor (A-ALD) products are developed to ensure the provision of atmospheric layer products in continuation of the heritage from the Cloud–Aerosol Lidar and Infrared Pathfinder Satellite Observations (CALIPSO). Moreover, the products serve as input for synergistic algorithms that make use of data from ATLID and MSI. Therefore, the products are provided on the EarthCARE joint standard grid (JSG). A wavelet covariance transform (WCT) method with flexible thresholds is applied to determine layer boundaries from the ATLID Mie co-polar signal. Strong features detected with a horizontal resolution of 1 JSG pixel (approximately 1 km) or 11 JSG pixels are classified as thick or thin clouds, respectively. The top height of the uppermost cloud layer together with information on cloud layering are stored in the A-CTH product for further use in the generation of the ATLID-MSI Cloud Top Height (AM-CTH) synergy product. Aerosol layers are detected as weaker features at a resolution of 11 JSG pixels. Layer-mean optical properties are calculated from the ATLID L2a Extinction, Backscatter and Depolarization (A-EBD) product and stored in the A-ALD product, which also contains the aerosol optical thickness (AOT) of each layer, the stratospheric AOT, and the AOT of the entire atmospheric column. The latter parameter is used to produce the synergistic ATLID-MSI Aerosol Column Descriptor (AM-ACD) later in the processing chain. Several quality criteria are applied in the generation of A-CTH and A-ALD, and respective information is stored in the products. The functionality and performance of the algorithms are demonstrated by applying them to common EarthCARE test scenes. Conclusions are drawn for the application to real-world data and the validation of the products after the launch of EarthCARE.

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EarthCARE激光雷达观测的云顶高度和气溶胶层特性：A-CTH和A-ALD产品

摘要地球云上的高光谱分辨率大气激光雷达（ATLID）、气溶胶和辐射探测器（EarthCARE）以前所未有的精度提供了气溶胶和云的垂直分辨率信息。与同一平台上的云剖面雷达（CPR）、多光谱成像仪（MSI）和宽带辐射计（BBR）一起，它可以对全球范围内与气溶胶、云、降水和辐射相互作用有关的大气过程进行新的协同观察。本文描述了根据ATLID 1b级（L1b）和2a级（L2a）输入数据确定云顶高度和气溶胶层信息的算法。ATLID L2a云顶高度（A-CTH）和气溶胶层描述符（A-ALD）产品的开发是为了确保提供大气层产品，以延续云-气溶胶激光雷达和红外探路卫星观测（CALIPSO）的遗产。此外，这些产品还可以作为协同算法的输入，这些算法利用了ATLID和MSI的数据。因此，产品是在EarthCARE联合标准网格（JSG）上提供的。应用具有灵活阈值的小波协方差变换（WCT）方法从ATLID-Mie同极信号中确定层边界。检测到水平分辨率为1 JSG像素（约1 km）或11个JSG像素分别被分类为厚云或薄云。最上层云层的顶部高度与关于云分层的信息一起存储在A-CTH产品中，用于在ATLID-MSI-云顶高度（AM-CTH）协同产品的生成中进一步使用。气溶胶层在11个JSG像素的分辨率下被检测为较弱的特征。层平均光学性质由ATLID L2a消光、后向散射和去极化（A-EBD）产品计算，并存储在A-ALD产品中，该产品还包含每层的气溶胶光学厚度（AOT）、平流层AOT和整个大气柱的AOT。后一个参数用于在稍后的处理链中产生协同的ATLID-MSI-气溶胶柱描述符（AM-ACD）。在A-CTH和A-ALD的生成中应用了几个质量标准，并将相应的信息存储在产品中。通过将算法应用于常见的EarthCARE测试场景，展示了算法的功能和性能。得出了应用于真实世界数据和EarthCARE推出后产品验证的结论。

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来源期刊

Atmospheric Measurement Techniques METEOROLOGY & ATMOSPHERIC SCIENCES-

CiteScore

7.10

自引率

18.40%

发文量

331

审稿时长

3 months

期刊介绍： Atmospheric Measurement Techniques (AMT) is an international scientific journal dedicated to the publication and discussion of advances in remote sensing, in-situ and laboratory measurement techniques for the constituents and properties of the Earth’s atmosphere. The main subject areas comprise the development, intercomparison and validation of measurement instruments and techniques of data processing and information retrieval for gases, aerosols, and clouds. The manuscript types considered for peer-reviewed publication are research articles, review articles, and commentaries.