Mapping snow depth on Canadian sub-arctic lakes using ground-penetrating radar

IF 4.4 2区地球科学 Q1 GEOGRAPHY, PHYSICAL

Cryosphere Pub Date : 2023-06-15 DOI:10.5194/tc-17-2367-2023

Alicia F. Pouw, H. Kheyrollah Pour, Alex Maclean

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引用次数: 1

Abstract

Abstract. Ice thickness across lake ice is mainly influenced by the presence of snow and its distribution, which affects the rate of lake ice growth. The distribution of snow depth over lake ice varies due to wind redistribution and snowpack metamorphism, affecting the variability of lake ice thickness. Accurate and consistent snow depth data on lake ice are sparse and challenging to obtain. However, high spatial resolution lake snow depth observations are necessary for the next generation of thermodynamic lake ice models to improve the understanding of how the varying distribution of snow depth influences lake ice formation and growth. This study was conducted using ground-penetrating radar (GPR) acquisitions with ∼9 cm sampling resolution along transects totalling ∼44 km to map snow depth over four Canadian sub-arctic freshwater lakes. The lake snow depth derived from GPR two-way travel time (TWT) resulted in an average relative error of under 10 % when compared to 2430 in situ snow depth observations for the early and late winter season. The snow depth derived from GPR TWTs for the early winter season was estimated with a root mean square error (RMSE) of 1.6 cm and a mean bias error of 0.01 cm, while the accuracy for the late winter season on a deeper snowpack was estimated with a RMSE of 2.9 cm and a mean bias error of 0.4 cm. The GPR-derived snow depths were interpolated to create 1 m spatial resolution snow depth maps. The findings showed improved lake snow depth retrieval accuracy and introduced a fast and efficient method to obtain high spatial resolution snow depth information. The results suggest that GPR acquisitions can be used to derive lake snow depth, providing a viable alternative to manual snow depth monitoring methods. The findings can lead to an improved understanding of snow and lake ice interactions, which is essential for northern communities' safety and wellbeing and the scientific modelling community.

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利用探地雷达测绘加拿大亚北极湖泊的雪深

摘要湖冰的厚度主要受积雪的存在和分布的影响，而积雪的存在和分布又影响湖冰的生长速度。湖冰上积雪深度分布受风再分布和积雪变质作用的影响，影响湖冰厚度的变率。准确和一致的湖冰雪深数据是稀疏的，很难获得。然而，高空间分辨率的湖雪深观测对于下一代湖冰热力学模式是必要的，以提高对雪深变化分布如何影响湖冰形成和生长的理解。本研究利用探地雷达(GPR)采集数据，沿总长约44公里的样带采样分辨率为~ 9厘米，绘制了四个加拿大亚北极淡水湖的雪深图。利用探地雷达双向行时(TWT)反演的湖泊雪深值与2430次冬季前期和后期现场雪深值相比，平均相对误差在10%以下。GPR行波波对初冬积雪深度的估计精度RMSE为1.6 cm，平均偏差为0.01 cm，而冬末积雪深度的估计精度RMSE为2.9 cm，平均偏差为0.4 cm。将gpr反演的雪深插值生成1m空间分辨率的雪深图。研究结果提高了湖泊雪深反演精度，为获取高空间分辨率雪深信息提供了一种快速有效的方法。结果表明，探地雷达采集数据可用于湖泊雪深反演，为人工雪深监测提供了一种可行的替代方法。这些发现可以提高对雪和湖冰相互作用的理解，这对北方社区的安全和福祉以及科学建模社区至关重要。

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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来源期刊

Cryosphere GEOGRAPHY, PHYSICAL-GEOSCIENCES, MULTIDISCIPLINARY

CiteScore

8.70

自引率

17.30%

发文量

240

审稿时长

4-8 weeks

期刊介绍： The Cryosphere (TC) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on all aspects of frozen water and ground on Earth and on other planetary bodies. The main subject areas are the following: ice sheets and glaciers; planetary ice bodies; permafrost and seasonally frozen ground; seasonal snow cover; sea ice; river and lake ice; remote sensing, numerical modelling, in situ and laboratory studies of the above and including studies of the interaction of the cryosphere with the rest of the climate system.

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