强烈的夏季洪水可能导致底栖生物呼吸速率延长一年以上,导致河流溶解氧低

IF 3.1 Q2 GEOSCIENCES, MULTIDISCIPLINARY Journal of Hydrology X Pub Date : 2020-08-01 DOI:10.1016/j.hydroa.2020.100056
M.G. Hutchins , G. Harding , H.P. Jarvie , T.J. Marsh , M.J. Bowes , M. Loewenthal
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引用次数: 14

摘要

向河流系统供应易于降解的有机物会对缓慢流动的水体中的溶解氧(DO)造成压力。为了探索这一威胁,对泰晤士河(英国)进行了为期六年(2009-14)的多学科研究。利用不同时间分辨率(每月到每小时)的观测结果、基于物理的河网水质模型(QUESTOR)和估计代谢状态的分析工具(Delta法),研究期间发现了10个百分位DO浓度(10-DO,表明夏季低水平)的下降。评估工具表明,10-DO的减少是由于底栖异养呼吸的增加。水文和溶解有机碳(DOC)数据表明,10-DO的变化可归因于2012年夏季洪水以及随后将可降解有机物冲入河流的通道的连接。与2009-10年和2013-14年相比,流域出口(Windsor)的10-DO下降了7.0%,而上游水体的DOC浓度中值增加了5.5-48.1%。在此背景下,还确定并讨论了河上一个地点的10-DO异常相反趋势。目前,缺乏对底栖生物呼吸速率时空变异性的过程理解阻碍了模型对河流DO的预测。本文的研究结果表明,气候驱动的变化和城市化如何在复杂的集水区系统中导致水质脆弱性的持续中期变化。
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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Intense summer floods may induce prolonged increases in benthic respiration rates of more than one year leading to low river dissolved oxygen

The supply of readily-degradable organic matter to river systems can cause stress to dissolved oxygen (DO) in slow-flowing waterbodies. To explore this threat, a multi-disciplinary study of the River Thames (UK) was undertaken over a six-year period (2009–14). Using a combination of observations at various time resolutions (monthly to hourly), physics-based river network water quality modelling (QUESTOR) and an analytical tool to estimate metabolic regime (Delta method), a decrease in 10th percentile DO concentration (10-DO, indicative of summer low levels) was identified during the study period. The assessment tools suggested this decrease in 10-DO was due to an increase in benthic heterotrophic respiration. Hydrological and dissolved organic carbon (DOC) data showed that the shift in 10-DO could be attributed to summer flooding in 2012 and consequent connection of pathways flushing degradable organic matter into the river. Comparing 2009–10 and 2013–14 periods, 10-DO decreased by 7.0% at the basin outlet (Windsor) whilst median DOC concentrations in a survey of upstream waterbodies increased by 5.5–48.1%. In this context, an anomalous opposing trend in 10-DO at one site on the river was also identified and discussed. Currently, a lack of process understanding of spatio-temporal variability in benthic respiration rates is hampering model predictions of river DO. The results presented here show how climatic-driven variation and urbanisation induce persistent medium-term changes in the vulnerability of water quality to multiple stressors across complex catchment systems.

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来源期刊
Journal of Hydrology X
Journal of Hydrology X Environmental Science-Water Science and Technology
CiteScore
7.00
自引率
2.50%
发文量
20
审稿时长
25 weeks
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