Mountain snow depth retrievals from customized processing of ICESat-2 satellite laser altimetry

IF 11.1 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES
Hannah Besso, David Shean, Jessica D. Lundquist
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引用次数: 0

Abstract

Snow depth is highly variable across basins, yet most snow depth data in the western U.S. come from sparse in situ point measurements. The water resources community needs accurate snow depth data for improved basin-wide snow depth estimates. The NASA ICESat-2 mission has provided over four years of global satellite laser altimetry measurements since October 2018. Previous studies have shown that standard ICESat-2 data products, when combined with snow-off digital terrain models (DTMs) from airborne laser scanning, have the potential to provide snow depth measurements with varying accuracy depending on factors such as surface slope and canopy cover. In this study we show that ICESat-2 snow depth measurements can be improved with customized data products generated using the SlideRule Earth service. Here we investigate the accuracy of our ICESat-2 SlideRule snow depth method using four years (2019–2022) of reference in situ snow depth measurements and airborne lidar snow depth observations for two watersheds with varying terrain characteristics: the Tuolumne River basin above Hetch Hetchy, CA and the Methow Valley, WA. We observe median differences of −0.14 m (RMSE of 0.18 m) and −0.20 m (RMSE of 0.33 m) between our ICESat-2 snow depth measurements and reference snow depth measurements for the Tuolumne Basin and Methow Valley sites, respectively. While individual ICESat-2 elevation measurements can contain noise, basin-scale aggregation offers robust statistics for snow depth. Differences in accuracy between sites are attributed to terrain characteristics and their spatial distributions. The customized ICESat-2 SlideRule data products used in this study resulted in more accurate median snow depth values, including under canopy, than those found by previous studies using standard ICESat-2 data products in mid-latitude mountainous regions. When combined with snow-off DTMs, the aggregated snow-on ICESat-2 SlideRule observations could provide a new snow depth dataset across the western U.S. and potentially global land surfaces.

ICESat-2卫星激光测高定制处理的山区积雪深度反演
不同盆地的雪深变化很大,但美国西部的大多数雪深数据来自稀疏的现场点测量。水资源界需要准确的雪深数据来改进全流域的雪深估计。自2018年10月以来,美国国家航空航天局ICESat-2任务已经提供了四年多的全球卫星激光测高测量。先前的研究表明,标准ICESat-2数据产品与机载激光扫描的雪外数字地形模型(DTM)相结合,有可能根据地表坡度和冠层覆盖等因素提供不同精度的雪深测量。在这项研究中,我们展示了ICESat-2雪深测量可以通过使用SlideRule地球服务生成的定制数据产品来改进。在这里,我们使用四年(2019-2022年)的参考原位雪深测量和机载激光雷达雪深观测,研究了ICESat-2 SlideRule雪深方法的准确性,这两个流域具有不同的地形特征:加利福尼亚州赫奇-赫奇上方的Tuolumne河流域和华盛顿州的Methow山谷。我们观察到,在Tuolumme盆地和Methow山谷的ICESat-2雪深测量值和参考雪深测量结果之间,分别存在−0.14 m(均方根误差0.18 m)和−0.20 m(均均方根误差0.33 m)的中值差异。虽然单独的ICESat-2高程测量可能包含噪声,但盆地规模的聚集提供了雪深的可靠统计数据。场地之间精度的差异归因于地形特征及其空间分布。本研究中使用的定制ICESat-2 SlideRule数据产品比之前在中纬度山区使用标准ICESat-2数据产品的研究发现的雪深中值(包括冠层下)更准确。当与DTM外的雪相结合时,ICESat-2 SlideRule观测到的聚集雪可以为美国西部和潜在的全球地表提供一个新的雪深数据集。
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来源期刊
Remote Sensing of Environment
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.
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