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+ | ==Introduction== | ||
+ | Groundwater contaminated with metals and metalloids (collectively referred to as “metals” in this article for simplicity; Table 1) can be a major problem because of the broad spectrum of sources, the toxicity of many metals, and the difficulty in remediating metal-contaminated sites. Common metal contaminants, their primary sources, and their potential health effects, especially those that occur at U.S. Department of Defense<ref>Fabian, G. and Watts, K., 2005. Army small arms training range environmental best practices (BMPs) Manual. DTC Project No. 9-CO-160-000-504, U.S. Army Environmental Center, Aberdeen Proving Ground, MD. [http://www.environmentalrestoration.wiki/images/c/c0/Fabian-2005-Army-Small-Arms-Training-Range-BMP.pdf Report pdf]</ref><ref>United States Government Accountability Office (GAO), 2005. Groundwater contamination – DOD uses and develops a range of remediation technologies to clean up military sites. Report to congressional committees, GAO-05-666. [http://www.environmentalrestoration.wiki/images/e/ea/GAO-2005-GW_Contamination_-_DOD_Uses_and_Develops_a_Range_of_Remed_Technologies_.pdf Report pdf]</ref><ref>Hering, J.G., Burris, D., Reisinger, H.J., O’Day, P., 2008. Environmental fate and exposure assessment for arsenic in groundwater. SERDP Project ER-1374. [https://www.serdp-estcp.org/Program-Areas/Environmental-Restoration/Contaminants-on-Ranges/Protecting-Groundwater-Resources/ER-1374 ER-1374]</ref>, U.S. Department of Energy<ref>Riley, R.G. and Zachara, J.M., 1992. Chemical contaminants on DOE lands and selection of contaminant mixtures for subsurface science research. U.S. Department of Energy (No. DOE/ER--0547T). [http://www.environmentalrestoration.wiki/images/6/68/Riley-1992-Chemical_Contaminants_on_DOE_Lands_and_Selection_of_Contaminant_Mix.pdf Report pdf]</ref><ref>Hazen, T.C., Faybishenko, B., Jordan, P., 2008. Complexity of Groundwater Contaminants at DOE Sites. LBNL-4117E, Lawrence Berkeley National Laboratory. [http://www.environmentalrestoration.wiki/images/4/4e/Hazen-2008-Complexity_of_GW_at_DOE_Sites.pdf Report pdf]</ref>, and private sites<ref name = "USGS2016">United States Geological Survey (USGS). Contaminants found in groundwater. [http://water.usgs.gov/edu/groundwater-contaminants.html USGS Website]</ref><ref>World Health Organization (WHO), 2016. Ten chemicals of major public health concern. [http://www.who.int/ipcs/assessment/public_health/chemicals_phc/en/ WHO Website[</ref> are quite variable (e.g., Table 1). The behavior of metal contaminants in groundwater depends on the nature of the source, the chemistry of the metal, and the mineralogy of the aquifer. Regulation and remediation of metal contaminants is further complicated by the fact that metals occur naturally in aquifers, sometimes at levels that are safe for ingestion, but at other times at concentrations that naturally exceed acceptable risk-based concentrations such as [https://en.wikipedia.org/wiki/Maximum_Contaminant_Level Maximum Concentration Levels ('''MCLs''')]. | ||
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+ | {| class="wikitable" style="margin-left: auto; margin-right: auto; border: none;" | ||
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+ | !style="background-color:#CEE0F2;"|Metal or Metalloid* !! style="background-color:#CEE0F2;"|Potential Natural and Man-Made Sources to Groundwater!! style="background-color:#CEE0F2;"|Potential Health and Other Effects If Concentrations are Above Risk-Based Levels!! style="background-color:#CEE0F2;"| MCL<ref>U.S. Environmental Protection Agency (USEPA), 2016. Table of Regulated Drinking Water Contaminants.[http://www.epa.gov/your-drinking-water/table-regulated-drinking-water-contaminants Table of Regulated Drinking Water]</ref>(mg/L) | ||
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+ | | Antimony*|| Enters environment from natural weathering, industrial production, municipal waste disposal, and manufacturing of flame retardants, ceramics, glass, batteries, fireworks, explosives, and ammunition.|| Decreases longevity, alters blood levels of glucose and cholesterol in laboratory animals exposed at high levels over their lifetime.|| 0.006 | ||
+ | |- | ||
+ | | Arsenic*|| Enters environment from natural processes, industrial activities, pesticides, industrial waste, smelting of copper, lead, and zinc.|| Causes acute and chronic toxicity, liver and kidney damage, decreases hemoglobin, carcinogenic.|| 0.010 | ||
+ | |- | ||
+ | | Cadmium|| May enter the environment from industrial discharge, mining waste, metal/metalloid plating, water pipes, batteries, paints and pigments, plastic stabilizers, and landfill leachate.|| Replaces zinc biochemically in the body and causes high blood pressure, liver and kidney damage. Destroys testicular tissue and red blood cells. Toxic to aquatic biota.|| 0.005 | ||
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+ | | Chromium|| Used in metal/metalloid plating and as a cooling water additive. Also may enter environment from old mining operations runoff and leaching into groundwater.|| Chromium (III) is a nutritionally essential element. Chromium (VI) is more toxic, causing liver and kidney damage, internal hemorrhaging, respiratory damage, dermatitis, and ulcers on the skin at high concentrations.||0.1 (total) | ||
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+ | | Copper|| Enters environment from metal/metalloid plating, industrial and domestic waste, mining, and mineral leaching.|| An essential nutrient in low doses. High doses can cause stomach and intestinal distress, liver and kidney damage, anemia. Essential trace element but toxic to plants and algae at moderate doses.|| 1.3 | ||
+ | |- | ||
+ | | Lead|| Enters environment from industry, mining, plumbing, leaded-gasoline, and recycling of lead-acid batteries.|| Affects red blood cell chemistry; delays normal physical and mental development in babies and young children. Can cause deficits in attention span, hearing, and learning in children.|| 0.015 | ||
+ | |- | ||
+ | | Mercury|| Enters environment from industrial waste (e.g., chloralkali process), mining, pesticides, coal, electrical equipment e.g., batteries, lamps, switches), smelting, and fossil-fuel combustion.|| Causes acute and chronic toxicity. Targets the kidneys and can cause nervous system disorders.|| 0.002 | ||
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+ | | Uranium|| Enters groundwater from uranium mining and ore processing operations, nuclear fuel reprocessing facilities, and potentially from exploded depleted uranium munitions.|| Depresses renal function, can cause kidney damage and failure in extreme cases. More of a toxicological problem than a radiation problem, though long-term exposure can increase risk of cancer.|| 0.030 | ||
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+ | | Zinc|| Enters environment from industrial waste, metal/metalloid plating, plumbing, and is a major component of various industrial sludges.|| Essential nutrient. Causes detrimental effects in humans at high doses. Can be toxic to aquatic organisms.|| 5<ref>U.S. Environmental Protection Agency (USEPA), 2016. Secondary drinking water standards: guidance for nuisance chemicals. [https://www.epa.gov/dwstandardsregulations/secondary-drinking-water-standards-guidance-nuisance-chemicals Webpage]</ref>(secondary) | ||
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+ | | colspan="12" style="color:black;text-align:left;"|Table 1: Several metal/metalloid contaminants of concern in groundwater. (Revised from<ref name = "USGS2016"/>). | ||
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Revision as of 19:09, 1 November 2016
Metals and metalloids (an element such as arsenic or antimony with properties in between those of metals and nonmetals are common groundwater contaminants that present a risk to users of groundwater if concentrations exceed acceptable risk-based concentrations. Contamination of groundwater by metals and metalloids is most often related to industrial sources or mining and mineral processing. Their acute and chronic toxicity as well as their common occurrence, make metal and metalloid contamination environmentally significant. The behavior and toxicity of metals and metalloids can vary with the chemical composition of the groundwater and the minerals present in the aquifer. Under some conditions, a given metal or metalloid may pose little risk because it is adsorbed to the aquifer solids or precipitated from groundwater before it reaches any exposure point. In other cases these contaminants may be quite mobile, forming groundwater plumes that can pose a risk to groundwater users.
Contents
Related Articles:
- Mobility of Metals and Metalloid Contaminants in Groundwater
- Monitored Natural Attenuation (MNA) of Metals and Metalloids
- Remediation of Metals and Metalloids
CONTRIBUTOR(S): Dr. Miles Denham
Key Resource(s):
Introduction
Groundwater contaminated with metals and metalloids (collectively referred to as “metals” in this article for simplicity; Table 1) can be a major problem because of the broad spectrum of sources, the toxicity of many metals, and the difficulty in remediating metal-contaminated sites. Common metal contaminants, their primary sources, and their potential health effects, especially those that occur at U.S. Department of Defense[1][2][3], U.S. Department of Energy[4][5], and private sites[6][7] are quite variable (e.g., Table 1). The behavior of metal contaminants in groundwater depends on the nature of the source, the chemistry of the metal, and the mineralogy of the aquifer. Regulation and remediation of metal contaminants is further complicated by the fact that metals occur naturally in aquifers, sometimes at levels that are safe for ingestion, but at other times at concentrations that naturally exceed acceptable risk-based concentrations such as Maximum Concentration Levels (MCLs).
Metal or Metalloid* | Potential Natural and Man-Made Sources to Groundwater | Potential Health and Other Effects If Concentrations are Above Risk-Based Levels | MCL[8](mg/L) | ||||||||
---|---|---|---|---|---|---|---|---|---|---|---|
Antimony* | Enters environment from natural weathering, industrial production, municipal waste disposal, and manufacturing of flame retardants, ceramics, glass, batteries, fireworks, explosives, and ammunition. | Decreases longevity, alters blood levels of glucose and cholesterol in laboratory animals exposed at high levels over their lifetime. | 0.006 | ||||||||
Arsenic* | Enters environment from natural processes, industrial activities, pesticides, industrial waste, smelting of copper, lead, and zinc. | Causes acute and chronic toxicity, liver and kidney damage, decreases hemoglobin, carcinogenic. | 0.010 | ||||||||
Cadmium | May enter the environment from industrial discharge, mining waste, metal/metalloid plating, water pipes, batteries, paints and pigments, plastic stabilizers, and landfill leachate. | Replaces zinc biochemically in the body and causes high blood pressure, liver and kidney damage. Destroys testicular tissue and red blood cells. Toxic to aquatic biota. | 0.005 | ||||||||
Chromium | Used in metal/metalloid plating and as a cooling water additive. Also may enter environment from old mining operations runoff and leaching into groundwater. | Chromium (III) is a nutritionally essential element. Chromium (VI) is more toxic, causing liver and kidney damage, internal hemorrhaging, respiratory damage, dermatitis, and ulcers on the skin at high concentrations. | 0.1 (total) | ||||||||
Copper | Enters environment from metal/metalloid plating, industrial and domestic waste, mining, and mineral leaching. | An essential nutrient in low doses. High doses can cause stomach and intestinal distress, liver and kidney damage, anemia. Essential trace element but toxic to plants and algae at moderate doses. | 1.3 | ||||||||
Lead | Enters environment from industry, mining, plumbing, leaded-gasoline, and recycling of lead-acid batteries. | Affects red blood cell chemistry; delays normal physical and mental development in babies and young children. Can cause deficits in attention span, hearing, and learning in children. | 0.015 | ||||||||
Mercury | Enters environment from industrial waste (e.g., chloralkali process), mining, pesticides, coal, electrical equipment e.g., batteries, lamps, switches), smelting, and fossil-fuel combustion. | Causes acute and chronic toxicity. Targets the kidneys and can cause nervous system disorders. | 0.002 | ||||||||
Uranium | Enters groundwater from uranium mining and ore processing operations, nuclear fuel reprocessing facilities, and potentially from exploded depleted uranium munitions. | Depresses renal function, can cause kidney damage and failure in extreme cases. More of a toxicological problem than a radiation problem, though long-term exposure can increase risk of cancer. | 0.030 | ||||||||
Zinc | Enters environment from industrial waste, metal/metalloid plating, plumbing, and is a major component of various industrial sludges. | Essential nutrient. Causes detrimental effects in humans at high doses. Can be toxic to aquatic organisms. | 5[9](secondary) | ||||||||
Table 1: Several metal/metalloid contaminants of concern in groundwater. (Revised from[6]). |
References
- ^ Fabian, G. and Watts, K., 2005. Army small arms training range environmental best practices (BMPs) Manual. DTC Project No. 9-CO-160-000-504, U.S. Army Environmental Center, Aberdeen Proving Ground, MD. Report pdf
- ^ United States Government Accountability Office (GAO), 2005. Groundwater contamination – DOD uses and develops a range of remediation technologies to clean up military sites. Report to congressional committees, GAO-05-666. Report pdf
- ^ Hering, J.G., Burris, D., Reisinger, H.J., O’Day, P., 2008. Environmental fate and exposure assessment for arsenic in groundwater. SERDP Project ER-1374. ER-1374
- ^ Riley, R.G. and Zachara, J.M., 1992. Chemical contaminants on DOE lands and selection of contaminant mixtures for subsurface science research. U.S. Department of Energy (No. DOE/ER--0547T). Report pdf
- ^ Hazen, T.C., Faybishenko, B., Jordan, P., 2008. Complexity of Groundwater Contaminants at DOE Sites. LBNL-4117E, Lawrence Berkeley National Laboratory. Report pdf
- ^ 6.0 6.1 United States Geological Survey (USGS). Contaminants found in groundwater. USGS Website
- ^ World Health Organization (WHO), 2016. Ten chemicals of major public health concern. [http://www.who.int/ipcs/assessment/public_health/chemicals_phc/en/ WHO Website[
- ^ U.S. Environmental Protection Agency (USEPA), 2016. Table of Regulated Drinking Water Contaminants.Table of Regulated Drinking Water
- ^ U.S. Environmental Protection Agency (USEPA), 2016. Secondary drinking water standards: guidance for nuisance chemicals. Webpage