英国河流流域营养物质浓度的机器学习估计

IF 2.6 Q2 WATER RESOURCES
Chak-Hau Michael Tso, Eugene Magee, David Huxley, Michael Eastman, Matthew Fry
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引用次数: 0

摘要

氮(N)和磷(P)是水生生态系统中植物生长和维持生命所必需的营养物质。然而,过量的氮和磷会导致藻类大量繁殖,耗尽氧气,导致鱼类死亡,并释放对人类有害的毒素。河流中氮和磷水平的估计通常是在站点或栅格(1公里)尺度上计算的;因此,很难想象水在下游流动时水质的演变。利用高分辨率河段尺度河网,并将每个河段与土地覆盖分数和集水区描述符相关联,我们使用来自英国环境局开放水质数据档案的2343个站点的汇总数据(2010-2020年)训练随机森林模型,以预测英国每个河段的长期硝酸盐和正磷酸盐浓度。我们将不同季节的模型训练和预测分开,以研究特征重要性的潜在差异。通过5倍交叉验证,我们的模型预测硝酸盐和正磷酸盐的平均检测系数(r2)分别为0.71和0.58。我们的模型在更高的斯特拉勒流订单中显示出稍好的性能,突出了在小流中进行预测的挑战。研究结果表明,耕地和园艺地利用是硝酸盐最强和最可靠的预测因子,而洪泛区范围和标准径流量百分比是正磷酸盐更强的预测因子。在全国范围内,城市化地区的正磷酸盐浓度较高。这项研究表明,将河网模型与机器学习相结合,可以很容易地提供对水质水平空间分布的河网理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
River reach-level machine learning estimation of nutrient concentrations in Great Britain
Nitrogen (N) and phosphorus (P) are essential nutrients necessary for plant growth and support life in aquatic ecosystems. However, excessive N and P can lead to algal blooms that deplete oxygen and lead to fish death and the release of toxins that are harmful to humans. Estimates of N and P levels in rivers are typically calculated at station or grid (>1 km) scale; therefore, it is difficult to visualise the evolution of water quality as water travels downstream. Using a high-resolution reach-scale river network and associating each reach with land cover fractions and catchment descriptors, we trained random forest models on aggregated data (2010–2020) from the Environmental Agency Open Water Quality Data Archive for 2,343 stations to predict long-term nitrate and orthophosphate concentrations at each river reach in Great Britain (GB). We separated the model training and predictions for different seasons to investigate the potential difference in feature importance. Our model predicted concentrations with an average testing coefficient of determination ( R 2 ) of 0.71 for nitrate and 0.58 for orthophosphate using 5-fold cross-validation. Our model showed slightly better performance for higher Strahler stream orders, highlighting the challenges of making predictions in small streams. Our results revealed that arable and horticultural land use is the strongest and most reliable predictor for nitrate, while floodplain extents and standard percentage runoff are stronger predictors for orthophosphate. Nationally, higher orthophosphate concentrations were observed in urbanised areas. This study shows how combining a river network model with machine learning can easily provide a river network understanding of the spatial distribution of water quality levels.
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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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