地下:气候和季节性的变化可能会增加地下流量的贡献,并改变农业流域的溶解养分输出

IF 2.5 3区 环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES Journal of Great Lakes Research Pub Date : 2024-12-01 Epub Date: 2024-10-11 DOI:10.1016/j.jglr.2024.102452
Karl Hanke , N.K. Singh , N.B. Basu , A. Michaud , W. Yang , M.L. Macrae
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引用次数: 0

摘要

气候变化正在改变气温以及降水事件的时间和强度,极端事件和冬季流量增加;预计下个世纪的变化还会加剧。这些变化可能会改变河流流量和养分输出,但这些变化的幅度和时间仍不确定。在这里,我们使用建模方法在加拿大安大略省探索这个问题。我们使用综合环流模型(GCMs)来迫使土壤水分评估工具(SWAT)在梅德韦溪流域(一个主要的农业流域,排放到圣克莱尔湖,最终进入伊利湖)内预测未来气候下的径流、悬浮沉积物、硝酸盐和总磷损失。在较高的气温和更大的降水强度和频率下,模式预测冬季流量显著增加(23-36%),其中大部分流量发生在地漏中。径流和水流路径的季节性变化预计会导致硝酸盐等溶解溶质浓度的增加(56% - 89%),总磷(25-47%)和悬浮沉积物浓度的小幅增加(5-14%)。由于流量和浓度都在增加,所有情景下的养分负荷都在增加,损失最大的时间发生在一年的早些时候。这项工作强调了了解气候变化对寒冷农业区砖瓦排水环境下非生长季节养分输出的驱动过程的重要性,并将帮助管理者制定更有效的长期流域管理计划。
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Going underground: Changing climate and flow seasonality may increase subsurface flow contribution and modify dissolved nutrient export from agricultural catchments
Climate change is changing air temperature as well as the timing and magnitude of precipitation events, with increasing extreme events and winter flows; and changes are expected to increase in the next century. Such changes would likely alter streamflow and nutrient export, there is still uncertainty on the magnitude and timing of these shifts. Here, we used a modeling approach to explore this question in Ontario, Canada. We used an ensemble of general circulation models (GCMs) to force the Soil Water Assessment Tool (SWAT) to project runoff, suspended sediment, nitrate and total phosphorus losses under future climates within the Medway Creek watershed, a predominantly agricultural watershed that discharges into Lake St. Clair and eventually Lake Erie. Under the warmer air temperatures and greater magnitude and frequency of precipitation projected by the GCM ensemble, the model projected a significant increase in winter flows (23–36%), with most of the flow occurring through tile drains. Shifts in the seasonality of runoff and flow pathways are anticipated to contribute to an increase in concentration of dissolved solutes like nitrate (56–89%), and smaller increases in total phosphorus (25–47%) and suspended sediment concentrations (5–14%). Given increases in both flows and concentrations, nutrient loads increase in all scenarios, with the timing of greatest losses occurring earlier in the year. This work highlights the importance of understanding processes driving non-growing season nutrient export with climate change in tile-drained settings in cool agricultural regions and will assist managers in developing more effective watershed management plans for the long-term.
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来源期刊
Journal of Great Lakes Research
Journal of Great Lakes Research 生物-海洋与淡水生物学
CiteScore
5.10
自引率
13.60%
发文量
178
审稿时长
6 months
期刊介绍: Published six times per year, the Journal of Great Lakes Research is multidisciplinary in its coverage, publishing manuscripts on a wide range of theoretical and applied topics in the natural science fields of biology, chemistry, physics, geology, as well as social sciences of the large lakes of the world and their watersheds. Large lakes generally are considered as those lakes which have a mean surface area of >500 km2 (see Herdendorf, C.E. 1982. Large lakes of the world. J. Great Lakes Res. 8:379-412, for examples), although smaller lakes may be considered, especially if they are very deep. We also welcome contributions on saline lakes and research on estuarine waters where the results have application to large lakes.
期刊最新文献
Editorial Board From fragmented efforts to binational strategy: Advancing the management of plastic pollution in the Laurentian Great Lakes basin Quantification of macroplastics and litter dynamics in a highly active bay of Lake Victoria Cyanotoxins in the Great Lakes basin and their removal in drinking water treatment plants Multidecadal trends and shifts in phytoplankton communities before, during, and post delisting of an Area of Concern in Lake Huron
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