Snow Depth Distribution in Canopy Gaps in Central Pyrenees

IF 3.2 3区 地球科学 Q1 Environmental Science
Francisco Rojas-Heredia, Jesús Revuelto, César Deschamps-Berger, Esteban Alonso-González, Pablo Domínguez-Aguilar, Jorge García, Fernando Pérez-Cabello, Juan Ignacio López-Moreno
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Abstract

This research analyses the snow depth distribution in canopy gaps across two plots in Central Pyrenees, to improve understanding of snow–forest and topography interactions. Snow depth maps, forest structure–canopy gap (FSCG) characteristics and topographic variables were generated by applying Structure from Motion algorithms (SfM) to images acquired from Unmanned Aerial Vehicles (UAVs). Six flights were conducted under different snowpack conditions in 2021, 2022 and 2023. Firstly, the snow depth database was analysed in terms of the ratio between the radius of the canopy gap and the maximum height of the surrounding trees (r/h), in order to classify the gaps as small-size, medium-size, large-size, or open areas at both sites independently. Then Kendall's correlation coefficients between the snow depth, FSCG and topographic variables were computed and a Random Forest (RF) model for each survey was implemented, to determine the influence of these variables in explaining snow depth patterns. The results demonstrate the consistency of the UAV SfM photogrammetry approach for measuring snowpack dynamics at fine scale in canopy gaps and open areas. At the northeast exposed Site 1, the larger the r/h observed, the greater was the snow depth obtained. This pattern was not evident at the southwest exposed Site 2, which presented high variability related to the survey dates and categories, highlighting the relevance of topography for determining optimum snow accumulation in forested areas. Slope systematically exhibited a negative and significant correlation with snow depth and was consistently the highest-ranked variable for explaining snow distribution at both sites according to the RF models. Distance to the Canopy Edge also presented high influence, especially at Site 1. The findings suggest differences in the main drivers throughout each site and surveys of the topographic and FSCG variables are needed to understand snow depth distribution over heterogeneous mountain forest domains.

Abstract Image

中比利牛斯山树冠间隙的雪深分布
本研究分析了比利牛斯山中部两个地块树冠间隙的雪深分布,以加深对雪-森林和地形相互作用的理解。通过对无人驾驶飞行器(UAV)获取的图像应用运动结构算法(SfM),生成了雪深图、森林结构-树冠间隙(FSCG)特征和地形变量。在 2021 年、2022 年和 2023 年的不同积雪条件下进行了六次飞行。首先,根据树冠缝隙半径与周围树木最大高度之比(r/h)对雪深数据库进行分析,从而将两个地点的缝隙分别划分为小型、中型、大型或空旷区域。然后计算了雪深、FSCG 和地形变量之间的肯德尔相关系数,并为每次调查建立了随机森林(RF)模型,以确定这些变量在解释雪深模式方面的影响。结果表明,无人机 SfM 摄影测量方法在树冠间隙和开阔区域的精细尺度积雪动态测量方面具有一致性。在东北部裸露的 1 号站点,观测到的 r/h 越大,获得的雪深就越大。这一模式在西南部裸露的 2 号站点并不明显,该站点与勘测日期和类别相关的变化很大,这突出表明了地形对于确定林区最佳积雪量的重要性。坡度与积雪深度呈显著负相关,根据射频模型,坡度一直是解释两个站点积雪分布的最高变量。距离树冠边缘的距离也有很大影响,尤其是在站点 1。研究结果表明,每个观测点的主要驱动因素存在差异,因此需要对地形和FSCG变量进行调查,以了解异质山地林区的积雪深度分布情况。
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来源期刊
Hydrological Processes
Hydrological Processes 环境科学-水资源
CiteScore
6.00
自引率
12.50%
发文量
313
审稿时长
2-4 weeks
期刊介绍: Hydrological Processes is an international journal that publishes original scientific papers advancing understanding of the mechanisms underlying the movement and storage of water in the environment, and the interaction of water with geological, biogeochemical, atmospheric and ecological systems. Not all papers related to water resources are appropriate for submission to this journal; rather we seek papers that clearly articulate the role(s) of hydrological processes.
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