The first global 883 GHz cloud ice survey: IceCube Level 1 data calibration, processing and analysis

Earth System Science Data Discussions Pub Date : 2021-05-26 DOI:10.5194/ESSD-2021-101

J. Gong, Dong L. Wu, P. Eriksson

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引用次数: 2

Abstract

Abstract. Sub-millimeter (sub-mm, 200–1000 GHz) wavelengths contribute a unique capability to fill-in the sensitivity gap between operational visible/infrared (VIS/IR) and microwave (MW) remote sensing for atmosphere cloud ice and snow. Being able of penetrating cloud to measure cloud ice mass and microphysical properties in the middle to upper troposphere, this is a critical spectrum range for us to understand the connection between cloud ice and precipitation processes. As the first space-borne 883 GHz radiometer, IceCube mission was NASA's latest effort in spaceflight demonstration of a commercial sub-mm radiometer technology. Successfully launched from the International Space Station, IceCube is essentially a free-running radiometer and collected valuable 15-month measurements of atmosphere and cloud ice. This paper describes the detailed procedures for Level 1 data calibration, processing and validation. The scientific quality and values of IceCube data are then discussed, including radiative transfer model validation and evaluation, as well as the unique spatial distribution and diurnal cycle of cloud ice that are revealed for the first time on a quasi-global scale at this frequency.

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全球首个883 GHz云冰调查:IceCube Level 1数据校准、处理和分析

摘要亚毫米(亚毫米，200-1000 GHz)波长提供了一种独特的能力，填补了大气云冰和雪的可见/红外(VIS/IR)和微波(MW)遥感之间的灵敏度差距。能够穿透云层测量对流层中高层的云冰质量和微物理性质，这是我们了解云冰与降水过程联系的关键光谱范围。作为首个星载883 GHz辐射计，冰立方任务是NASA在商用亚毫米辐射计技术的航天演示方面的最新努力。冰立方从国际空间站成功发射，本质上是一个自由运行的辐射计，收集了15个月来大气和云冰的宝贵测量数据。本文描述了一级数据校准、处理和验证的详细程序。然后讨论了冰立方数据的科学质量和价值，包括辐射传输模型的验证和评估，以及首次在准全球尺度上在该频率下揭示的独特的云冰空间分布和日循环。

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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Earth System Science Data Discussions

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