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<oai_dc:dc xmlns:dc="http://purl.org/dc/elements/1.1/" xmlns:oai_dc="http://www.openarchives.org/OAI/2.0/oai_dc/" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://www.openarchives.org/OAI/2.0/oai_dc/ http://www.openarchives.org/OAI/2.0/oai_dc.xsd">
  <dc:contributor>Casey J. Lee</dc:contributor>
  <dc:contributor>Darren A. Lytle</dc:contributor>
  <dc:contributor>Michael R. Schock</dc:contributor>
  <dc:creator>Edward G. Stets</dc:creator>
  <dc:date>2018</dc:date>
  <dc:description>&lt;p&gt;&lt;span&gt;Corrosion&amp;nbsp;in&amp;nbsp;water-distribution systems&amp;nbsp;is a costly problem and controlling corrosion is a primary focus of efforts to reduce lead (Pb) and copper (Cu) in tap water. High chloride concentrations can increase the tendency of water to cause corrosion in&amp;nbsp;distribution systems. The effects of chloride are also expressed in several indices commonly used to describe the potential corrosivity of water, the chloride-sulfate&amp;nbsp;mass ratio&amp;nbsp;(CSMR) and the Larson Ratio (LR). Elevated CSMR has been linked to the galvanic corrosion of Pb whereas LR is indicative of the corrosivity of water to iron and&amp;nbsp;steel. Despite the known importance of chloride, CSMR, and LR to the potential corrosivity of&amp;nbsp;water, monitoring&amp;nbsp;of seasonal and interannual changes in these parameters is not common among water purveyors. We analyzed&amp;nbsp;long-term trends&amp;nbsp;(1992–2012) and the current status (2010–2015) of chloride, CSMR, and LR in order to investigate the short and long-term&amp;nbsp;temporal variability&amp;nbsp;in potential corrosivity of US streams and rivers. Among all sites in the trend analyses, chloride, CSMR, and LR increased slightly, with median changes of 0.9&lt;/span&gt;&lt;span&gt;&amp;nbsp;&lt;/span&gt;&lt;span&gt;mg&lt;/span&gt;&lt;span&gt;&amp;nbsp;&lt;/span&gt;&lt;span&gt;L&lt;/span&gt;&lt;sup&gt;−&amp;nbsp;1&lt;/sup&gt;&lt;span&gt;, 0.08, and 0.01, respectively. However, urban-dominated sites had much larger increases, 46.9&lt;/span&gt;&lt;span&gt;&amp;nbsp;&lt;/span&gt;&lt;span&gt;mg&lt;/span&gt;&lt;span&gt;&amp;nbsp;&lt;/span&gt;&lt;span&gt;L&lt;/span&gt;&lt;sup&gt;−&amp;nbsp;1&lt;/sup&gt;&lt;span&gt;, 2.50, and 0.53, respectively. Median CSMR and LR in urban streams (4.01 and 1.34, respectively) greatly exceeded thresholds found to cause corrosion in water distribution systems (0.5 and 0.3, respectively).&amp;nbsp;Urbanization&amp;nbsp;was strongly correlated with elevated chloride, CSMR, and LR, especially in the most snow-affected areas in the study, which are most likely to use&amp;nbsp;road salt. The probability of Pb action-level exceedances (ALEs) in drinking water facilities increased along with raw surface water CSMR, indicating a statistical connection between surface&amp;nbsp;water chemistry&amp;nbsp;and corrosion in drinking water facilities. Optimal&amp;nbsp;corrosion controlwill require monitoring of critical constituents reflecting the potential corrosivity in surface waters.&lt;/span&gt;&lt;/p&gt;</dc:description>
  <dc:format>application/pdf</dc:format>
  <dc:identifier>10.1016/j.scitotenv.2017.07.119</dc:identifier>
  <dc:language>en</dc:language>
  <dc:publisher>Elsevier</dc:publisher>
  <dc:title>Increasing chloride in rivers of the conterminous U.S. and linkages to potential corrosivity and lead action level exceedances in drinking water</dc:title>
  <dc:type>article</dc:type>
</oai_dc:dc>