预测模型显示美国切萨皮克湾流域内淡水支流的电导率相对于背景水平有所升高。

IF 4.8 Q1 ENVIRONMENTAL SCIENCES
ACS ES&T water Pub Date : 2024-10-30 eCollection Date: 2024-11-08 DOI:10.1021/acsestwater.4c00589
Rosemary M Fanelli, Joel Moore, Charles C Stillwell, Andrew J Sekellick, Richard H Walker
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引用次数: 0

摘要

电导率(即比电导率或 SC)升高会对淡水水生生物造成渗透压力,并可能增加某些污染物的毒性。切萨皮克湾流域(CBW)城市地区的底栖大型无脊椎动物完整性指数有所下降,需要更多信息来了解这些下降是否可能是电导率升高造成的。利用国家水质门户网站的监测数据,为切萨皮克湾流域开发了一个 SC 预测模型。为整个 CBW 的非潮汐河段编制了代表 SC 来源的预测变量。随机森林模型用于预测四个时间段(1999-2001 年、2004-2006 年、2009-2011 年和 2014-2016 年)的 SC,然后与全国背景 SC 数据集进行比较,以量化偏离背景 SC 的情况。碳酸盐地质、不透水覆盖、森林覆盖和积雪深度是预测 SC 的最重要变量。观测和建模结果表明,积雪深度放大了不透水覆盖对 SC 的影响。据预测,CBW 三分之二的河段 SC 会升高,而且这些升高的情况在许多地区会长期存在。这些结果可用于压力源识别评估,以确定未来监测的优先次序,并确定可在哪些地方实施管理活动以减少盐碱化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Predictive Modeling Reveals Elevated Conductivity Relative to Background Levels in Freshwater Tributaries within the Chesapeake Bay Watershed, USA.

Elevated conductivity (i.e., specific conductance or SC) causes osmotic stress in freshwater aquatic organisms and may increase the toxicity of some contaminants. Indices of benthic macroinvertebrate integrity have declined in urban areas across the Chesapeake Bay watershed (CBW), and more information is needed about whether these declines may be due to elevated conductivity. A predictive SC model for the CBW was developed using monitoring data from the National Water Quality Portal. Predictor variables representing SC sources were compiled for nontidal reaches across the CBW. Random forests modeling was conducted to predict SC at four time periods (1999-2001, 2004-2006, 2009-2011, and 2014-2016), which were then compared to a national data set of background SC to quantify departures from background SC. Carbonate geology, impervious cover, forest cover, and snow depth were the most important variables for predicting SC. Observations and modeled results showed snow depth amplified the effect of impervious cover on SC. Elevated SC was predicted in two-thirds of reaches in the CBW, and these elevated conditions persisted over time in many areas. These results can be used in stressor identification assessments to prioritize future monitoring and to determine where management activities could be implemented to reduce salinization.

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CiteScore
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