Model and remote-sensing-guided experimental design and hypothesis generation for monitoring snow-soil–plant interactions

IF 2.6 Q2 WATER RESOURCES
H. Wainwright, B. Dafflon, E. Siirila‐Woodburn, Nicola Falco, Yuxin Wu, Ian Breckheimer, Rosemary W. H. Carroll
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Abstract

In this study, we develop a machine-learning (ML)-enabled strategy for selecting hillslope-scale ecohydrological monitoring sites within snow-dominated mountainous watersheds, with a particular focus on snow-soil–plant interactions. Data layers rely on spatial data layers from both remote sensing and hydrological model simulations. Specifically, a Landsat-based foresummer drought sensitivity index is used to define the dependency of the annual peak plant productivity on the Palmer drought severity index in the early growing season. Hydrological simulations provide the spatiotemporal dynamics of near-surface soil moisture and snow depth. In this framework, a regression analysis identifies the key hydrological variables relevant to the spatial heterogeneity of drought sensitivity. We then apply unsupervised clustering to these key variables, using the Gaussian mixture model, to group hillslopes into several zones that have divergent relationships regarding soil moisture, snow dynamics, and drought sensitivity. Using the datasets collected in the East River Watershed (Crested Butte, Colorado, United States), results show that drought sensitivity is significantly correlated with model-derived soil moisture and snow-free timing over space and time. The relationship is, however, non-linear, such that the correlation decreases above a threshold elevation and in a heavy snow year due to large snowpacks, lateral flow, and soil storage limitations. Clustering is then able to define the zones that have high or low sensitivity to drought, as well as the mid-elevation regions where sensitivity is associated with the topographic aspect and net potential radiation. In addition, the algorithm identifies the most representative hillslopes with road/trail access within each zone for installing monitoring sites. Our method also aims to significantly increase the use of ML and model-simulation results to guide critical zone and watershed monitoring activities.
模型和遥感指导下的实验设计与假设生成,用于监测雪-土壤-植物之间的相互作用
在本研究中,我们开发了一种基于机器学习(ML)的策略,用于在以积雪为主的山区流域内选择山坡尺度的生态水文监测点,重点关注积雪-土壤-植物之间的相互作用。数据层依赖于遥感和水文模型模拟的空间数据层。具体而言,基于大地遥感卫星的夏前干旱敏感性指数被用来定义植物年生产力峰值对生长季初期帕尔默干旱严重程度指数的依赖性。水文模拟提供了近地表土壤水分和积雪深度的时空动态。在此框架下,回归分析确定了与干旱敏感性空间异质性相关的关键水文变量。然后,我们利用高斯混合模型对这些关键变量进行无监督聚类,将山坡分为几个区域,这些区域在土壤水分、积雪动态和干旱敏感性方面具有不同的关系。利用在东河流域(美国科罗拉多州克雷斯特布特)收集的数据集,结果表明干旱敏感性与模型得出的土壤水分和无雪时间在空间和时间上有显著相关性。然而,这种关系是非线性的,在超过临界海拔和大雪年份时,由于大量积雪、横向流动和土壤存储限制,相关性会降低。通过聚类,可以确定对干旱敏感度高或低的区域,以及敏感度与地形面和净潜在辐射相关的中海拔区域。此外,该算法还能确定每个区域内最有代表性的山坡,并为安装监测点提供道路/小径通道。我们的方法还旨在大幅提高多变量模型和模型模拟结果的使用率,以指导临界区和流域监测活动。
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
Frontiers in Water
Frontiers in Water WATER RESOURCES-
CiteScore
4.00
自引率
6.90%
发文量
224
审稿时长
13 weeks
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