Can We Rely on Satellite Visible/Infrared Microphysical Retrievals of Boundary Layer Clouds in Partially Cloudy Scenes? Implications for Climate Research

IF 4.6 1区地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Geophysical Research Letters Pub Date : 2025-04-25 DOI:10.1029/2024GL113825

David Painemal, William L. Smith Jr., Siddhant Gupta, Richard Moore, Brian Cairns, Greg M. McFarquhar, Joseph O’Brien

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Abstract

This study addresses the longstanding question of the reliability of gridded visible/infrared satellite cloud properties in partially cloudy scenes. By using in-situ cloud probes and airborne Research Scanning Polarimeter (RSP) observations, we analyze bias changes in satellite retrievals from the Spinning Enhanced Visible Infra-Red Imager (SEVIRI) geostationary sensor during the ORACLES campaign. Biases in cloud optical depth (τ) and droplet effective radius (r_e) modestly change for cloud area fraction greater than 35%. The agreement between SEVIRI and RSP r_e substantially improves when the retrievals are averaged after removing pixels with τ < 3.0, yielding biases indistinguishable from overcast scenes. In addition, satellite and RSP show an excellent agreement for closed- and open-cell stratocumulus clouds, showing that the satellite retrievals capture spatial changes of r_e, and confirming that satellites can faithfully reproduce real physical features for optically thick and partially cloudy scenes. We demonstrate that a simple methodology can minimize uncertainties in satellite-based climate studies.

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局部多云场景中边界层云能否依靠卫星可见光/红外微物理反演？对气候研究的影响

本研究探讨了长期以来一直存在的问题，即部分多云场景中网格化可见光/红外卫星云属性的可靠性。通过使用原地云探测和机载研究扫描偏振计（RSP）观测数据，我们分析了在 ORACLES 活动期间旋转增强可见光红外成像仪（SEVIRI）地球静止传感器卫星检索的偏差变化。云光学深度（τ）和液滴有效半径（re）的偏差在云面积分数大于 35% 时变化不大。当剔除τ < 3.0的像素后进行平均检索时，SEVIRI和RSP re之间的一致性大大提高，产生的偏差与阴天场景无异。此外，卫星和 RSP 对闭合和开放层积云显示出极好的一致性，表明卫星检索捕捉到了再的空间变化，并证实卫星能够忠实地再现光学厚和部分多云场景的真实物理特征。我们证明，在基于卫星的气候研究中，一种简单的方法可以最大限度地减少不确定性。

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来源期刊

Geophysical Research Letters 地学-地球科学综合

CiteScore

9.00

自引率

9.60%

发文量

1588

审稿时长

2.2 months

期刊介绍： Geophysical Research Letters (GRL) publishes high-impact, innovative, and timely research on major scientific advances in all the major geoscience disciplines. Papers are communications-length articles and should have broad and immediate implications in their discipline or across the geosciences. GRLmaintains the fastest turn-around of all high-impact publications in the geosciences and works closely with authors to ensure broad visibility of top papers.