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Technical Factsheet on: LEAD
List of Contaminants
As part of the Drinking Water and Health pages, this fact sheet is part of a larger publication:
National Primary Drinking Water Regulations
Drinking Water Standards
MCLG: zero
Action Level: > 0.015 mg/L in more than 10 percent of tap water samples
HAL(child): none
Health Effects Summary
Acute: Lead can cause a variety of adverse health effects in humans. At relatively low levels of
exposure, these effects may include interference with red blood cell chemistry, delays in normal
physical and mental development in babies and young children, slight deficits in the attention
span, hearing, and learning abilities of children, and slight increases in the blood pressure of
some adults. It appears that some of these effects, particularly changes in the levels of certain
blood enzymes and in aspects of children's neurobehavioral development, may occur at blood
lead levels so low as to be essentially without a threshold.
Chronic: Chronic exposure to lead has been linked to cerebrovascular and kidney disease in
humans.
Cancer: Lead has the potential to cause cancer from a lifetime exposure at levels above the action
level.
Usage Patterns
Lead is the fifth most important metal in the USA economy in terms of consumption. Of this
approximately 85% of the primary lead is produced domestically and 40-50% is recovered and
recycled. Eighty eight percent of the lead mined in the US comes from seven mines in the New
Lead Belt in southeastern Missouri; the rest coming from eight mines in Colorado, Idaho, and
Utah. Three of the six USA lead smelters are from this region, the others are located in Idaho,
Montana, and Texas.
Release Patterns
Lead occurs in drinking water from two sources: (1) Lead in raw water supplies, i.e., source
water or distributed water, and (2) corrosion of plumbing materials in the water distribution
system (corrosion by-products). Most lead contamination is from corrosion by-products.
Occurrence in Source Water and Distributed Water. Based on a variety of water quality surveys,
EPA now estimates that approximately 600 groundwater systems and about 215 surface suppliers
may have water leaving the treatment plant with lead levels greater than 0.005 mg/L These two
sources together indicate that less than 1 percent of the public water systems in the United States
have water entering the distribution system with lead levels greater than 0.005 mg/L. These
systems serve less than 3 percent of people that receive their drinking water from public water
systems.
From 1987 to 1993, according to the Toxics Release Inventory lead compound releases to land
and water totalled nearly 144 million lbs., almost all of which was to land. These releases were
primarily from lead and copper smelting industries. The largest releases occurred in Missouri,
Arizona and Montana. The largest direct releases to water occurred in Ohio.
Occurrence as a Corrosion By-Product. Lead in drinking water results primarily from corrosion
of materials located throughout the distribution system containing lead and copper and from lead
and copper plumbing materials used to plumb public- and privately-owned structures connected
to the distribution system. The amount of lead in drinking water attributable to corrosion
by-products depends on a number of factors, including the amount and age of lead and copper
bearing materials susceptible to corrosion, how long the water is in contact with the lead
containing surfaces, and how corrosive the water in the system is toward these materials.
The potential sources of lead corrosion by-products found in drinking water can include: Water
service mains (rarely), lead goosenecks or pigtails, lead service lines and interior household
pipes, lead solders and fluxes used to connect copper pipes, alloys containing lead, including
some faucets made of brass or bronze.
Most public water systems serve at least some buildings with lead solder and/or lead service
lines. EPA estimates that there are about 10 million lead service lines/connections. About 20
percent of all public water systems have some lead service lines/connections within their
distribution system.
The amount of lead in drinking water depends heavily on the corrosivity of the water. All water
is corrosive to metal plumbing materials to some degree, even water termed noncorrosive or
water treated to make it less corrosive. The corrosivity of water to lead is influenced by water
quality parameters such as pH, total alkalinity, dissolved inorganic carbonate, calcium, and
hardness. Galvanic corrosion of lead into water also occurs with lead-soldered copper pipes, due
to differences in the electrochemical potential of the two metals. Grounding of household
electrical systems to plumbing may also exacerbate galvanic corrosion.
Environmental Fate
Lead may enter the environment during its mining, ore processing, smelting, refining use,
recycling or disposal. The initial means of entry is via the atmosphere. Lead may also enter the
atmosphere from the weathering of soil and volcanos, but these sources are minor compared with
anthropogenic ones.
Lead will be retained in the upper 2-5 cm of soil, especially soils with at least 5% organic matter
or a pH 5 or above. Leaching is not important under normal conditions. It is expected to slowly
undergo speciation to the more insoluble sulfate, sulfide, oxide, and phosphate salts.
Lead enters water from atmospheric fallout, runoff or wastewater; little is transferred from
natural ores. Metallic lead is attacked by pure water in the presence of oxygen, but if the water
contains carbonates and silicates, protective films are formed preventing further attack. That
which dissolves tends to form ligands. Lead is effectively removed from the water column to the
sediment by adsorption to organic matter and clay minerals, precipitation as insoluble salt, and
reaction with hydrous iron and manganese oxide. Under most circumstances, adsorption
predominates.
Lake sediment microorganisms are able to directly methylate certain inorganic lead compounds.
Under appropriate conditions, dissolution due to anaerobic microbial action may be significant in
subsurface environments. The mean percentage removal of lead during the activated sludge
process was 82% and was almost entirely due to the removal of the insoluble fraction by
adsorption onto the sludge floc and to a much lesser extent, precipitation.
The most stable form of lead in natural water is a function of the ions present, the pH, and the
redox potential. In oxidizing systems, the least soluble common forms are probably the
carbonate, hydroxide, and hydroxycarbonate. In reduced systems where sulfur is present, PbS is
the stable solid. The solubility of Pb is 10 ppb above pH 8, while near pH 6.5 the solubility can
approach or exceed 100 ppb. Pb(0) and Pb(+2) can be oxidatively methylated by naturally
occurring compounds such as methyl iodide and glycine betaine. This can result in the
dissolution of lead already bound to sediment or particulate matter.
Lead does not appear to bioconcentrate significantly in fish but does in some shellfish such as
mussels. Evidence suggests that lead uptake in fish is localized in the mucous on the epidermis,
the dermis, and scales so that the availability in edible portions do not pose a human health
danger.
Chemical/Physical Properties
CAS Number: 7439-92-1
Color/ Form/Odor: Bluish-white, silvery, gray metal, lustrous when freshly
cut.
Soil sorption coefficient: N/A; Low mobility in most soils, lowest at neutral
pH and high organic matter.
Common Ores: sulfide-Galena; oxide-Lanarkite; carbonate-Cerrusite;
sulfate-Anglesite
Bioconcentration Factor: Log BCFs for fish, 1.65; shellfish, 3.4
Solubilities:
acetate- 443 g/L at 20 deg C
arsenate- insoluble in cold water
carbonate- 0.0011 g/L at 20 deg C
chloride- 10 g/L cold water
chromate- 0.2 mg/L
nitrate- 376.5 g/L at 0 deg C
oxide- 0.05 g/L at 20 deg C
dioxide- insoluble
phosphate- insoluble
sulfate- 0.4 g/L
sulfide- insoluble
tetraethyl- 0.29 mg/L at 25 deg C
thiocyanate- 0.5 g/L at 20 deg C
thiosulfate- 0.3 g/L cold water
Other Regulatory Information
Monitoring: | For Lead | For Water Quality Parameters |
&$160; | At Home Taps | Within the Distribution System | At Entry to the Distribution System |
Monitoring Period |
Initial | Every 6 months | Every 6 months | Every 6 months |
After corrosion control installation | Every 6 months | Every 6 months | Every 2 weeks |
Reduced monitoring |
- Conditional | Once a year | Every 6 months | Every 2 weeks |
- Final | Every 3 years | Every 3 years | Every 2 weeks |
Analysis
Reference Source | Method Number |
EPA 800/4-83-043 | 239.2; 200.8; 200.9 |
Treatment/Best Available Technologies
Source water: Ion exchange; lime softening; reverse osmosis; coagulation/filtration
Corrosion Control: pH and alkalinity adjustment; calcium adjustment; silica- or phosphate-based
corrosion inhibition
Toxics Release Inventory - Water and Land Releases, 1987-93 (in pounds)
| Water | Land |
TOTALS | 970,827 | 143,058,771 |
Top Twelve States * |
---|
MO | 4,408 | 40,656,278
|
AZ | 771 | 23,240,625
|
MT | 0 | 20,822,517
|
UT | 4,600 | 11,881,000
|
TX | 1,988 | 11,515,211
|
OH | 127,990 | 5,196,522
|
IN | 62,894 | 4,851,940
|
TN | 7,140 | 2,095,489
|
IL | 26,601 | 1,930,000
|
WI | 1,310 | 1,350,960
|
MN | 0 | 1,313,895
|
NM | 0 | 1,060,880
|
Major Industries* |
---|
Lead smelting, refining | 31,423 | 68,996,819
|
Copper smelting | 5,371 | 34,942,505
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Steelworks, blast furn. | 379,849 | 18,149,696
|
Storage batteries | 0 | 1,867,292
|
China plumbing fixtures | 1,310 | 1,350,960
|
Iron foundries | 10,021 | 1,274,777
|
Copper mining | 0 | 1,240,000
|
* State/Industry totals only include facilities with releases greater than 100,000 lbs.
For Additional Information:
EPA can provide further regulatory and other general information:
EPA Safe Drinking Water Hotline - 800/426-4791
Other sources of toxicological and environmental fate data include:
Toxic Substance Control Act Information Line - 202/554-1404
Toxics Release Inventory, National Library of Medicine - 301/496-6531
Agency for Toxic Substances and Disease Registry - 404/639-6000
List of Contaminants
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