Environmental impacts of coal

From SourceWatch
Jump to navigation Jump to search
Coalswarm badge.gif

This article is part of the Coal Issues portal on SourceWatch, a project of Global Energy Monitor and the Center for Media and Democracy. See here for help on adding material to CoalSwarm.

Coal 101: What's Wrong with Coal?

There are numerous damaging environmental impacts of coal that occur through its mining, preparation, combustion, waste storage, and transport. This article provides an overview. Each topic is explored in greater depth in separate articles, as are several related topics:

  • Acid mine drainage (AMD) refers to the outflow of acidic water from coal mines or metal mines, often abandoned mines where ore- or coal mining activities have exposed rocks containing the sulphur-bearing mineral pyrite. Pyrite reacts with air and water to form sulphuric acid and dissolved iron, and as water washes through mines, this compound forms a dilute acid, which can wash into nearby rivers and streams.[1]
  • Coal dust stirred up during the mining process, as well as released during coal transport, which can cause severe and potentially deadly respiratory problems.[6]
  • Coal fires occur in both abandoned coal mines and coal waste piles. Internationally, thousands of underground coal fires are burning now. Global coal fire emissions are estimated to include 40 tons of mercury going into the atmosphere annually, and three percent of the world's annual carbon dioxide emissions.[7][8]
  • Coal combustion waste is the nation's second largest waste stream after municipal solid waste.[9] It is disposed of in landfills or "surface impoundments," which are lined with compacted clay soil, a plastic sheet, or both. As rain filters through the toxic ash pits year after year, the toxic metals are leached out into the local environment.[10][11]
  • Coal sludge, also known as slurry, is the liquid coal waste generated by washing coal. It is typically disposed of at impoundments located near coal mines, but in some cases it is directly injected into abandoned underground mines. Since coal sludge contains toxins, leaks or spills can endanger underground and surface waters.[2]
  • Greenhouse gas emissions caused by surface mining - According to a 2010 study, mountaintop removal mining releases large amounts of carbon through clearcutting and burning of trees and through releases of carbon in soil brought to the surface by mining operations. These greenhouse gas emissions amount to at least 7% of conventional power plant emissions.[14][15]
  • Loss or degradation of groundwater - Since coal seams are often serve as underground aquifers, removal of coal beds may result in drastic changes in hydrology after mining has been completed.
  • Radical disturbance of 8.4 million acres of farmland, rangeland, and forests, most of which has not been reclaimed -- See The footprint of coal
  • Heavy metals and coal - Coal contains many heavy metals, as it is created through compressed organic matter containing virtually every element in the periodic table - mainly carbon, but also heavy metals. The heavy metal content of coal varies by coal seam and geographic region. Small amounts of heavy metals can be necessary for health, but too much may cause acute or chronic toxicity (poisoning). Many of the heavy metals released in the mining and burning of coal are environmentally and biologically toxic elements, such as lead, mercury, nickel, tin, cadmium, antimony, and arsenic, as well as radio isotopes of thorium and strontium.[16][17][18]
  • Mercury and coal - Emissions from coal-fired power plants are the largest source of mercury in the United States, accounting for about 41 percent (48 tons in 1999) of industrial releases.[19]
  • Mountaintop removal mining and other forms of surface mining can lead to the drastic alteration of landscapes, destruction of habitat, damages to water supplies, and air pollution. Not all of these effects can be adequately addressed through coal mine reclamation.
  • Particulates and coal - Particulate matter (PM) includes the tiny particles of fly ash and dust that are expelled from coal-burning power plants.[21] Studies have shown that exposure to particulate matter is related to an increase of respiratory and cardiac mortality.[22] [23]
  • Radioactivity and coal - Coal contains minor amounts of the radioactive elements, uranium and thorium. When coal is burned, the fly ash contains uranium and thorium "at up to 10 times their original levels."[24]
  • Subsidence - Land subsidence may occur after any type of underground mining, but it is particularly common in the case of longwall mining.[25]
  • Sulfur dioxide and coal - Coal-fired power plants are the largest human-caused source of sulfur dioxide, a pollutant gas that contributes to the production of acid rain and causes significant health problems. Coal naturally contains sulfur, and when coal is burned, the sulfur combines with oxygen to form sulfur oxides.[26]
  • Thermal pollution from coal plants is the degradation of water quality by power plants and industrial manufacturers - when water used as a coolant is returned to the natural environment at a higher temperature, the change in temperature impacts organisms by decreasing oxygen supply, and affecting ecosystem composition.[27]
  • Toxins - According to a July 2011 NRDC report, "How Power Plants Contaminate Our Air and States" electricity generation in the U.S. releases 381,740,601 lbs. of toxic air pollution annually, or 49% of total national emissions, based on data from the EPA’s Toxic Release Inventory (2009 data, accessed June 2011). Power plants are the leading sources of toxic air pollution in all but four of the top 20 states by electric sector emissions.
  • Waste coal, also known as "culm," "gob," or "boney," is made up of unused coal mixed with soil and rock from previous mining operations. Runoff from waste coal sites can pollute local water supplies.[28]
  • Water pollution from coal includes the negative health and environmental effects from the mining, processing, burning, and waste storage of coal.

Global warming

Coal-fired power plants are responsible for one-third of America’s carbon dioxide (CO2) emissions—about the same amount as all transportation sources -- cars, SUVs, trucks, buses, planes, ships, and trains -- combined.[30]

A 1000 megawatt (MW) coal-fired power plant produces approximately the same amount of global warming as 1.2 million cars.[31]

Coal-to-liquids technology will have particularly intensive climate effects. According to the Environmental Protection Agency, using liquefied coal as a fuel source would produce 119 percent greater greenhouse gas emissions than using petroleum-based fuel.[32]

For 1999, the U.S. Energy Information Agency estimated that coal plants produced 2.095 pounds of carbon dioxide per kilowatt hour. This represented a 4% improvement from the 2.117 pounds per kilowatt hour in 1998.[33]

NASA scientist James Hansen, who reported to the U.S. Congress that climate change was underway in 1988, has been particularly critical of the coal industry, stating that coal contributes the largest percentage of anthropogenic carbon dioxide into the atmosphere.[34] He acknowledges that a molecule of carbon dioxide emitted from burning coal has the same effect as a molecule emitted from burning oil, but that the difference is where the fuel originally resides. He says that most oil comes from Russia and Saudi Arabia, and that no matter how fuel-efficient automobiles become, the oil will eventually be burned and the carbon dioxide emitted, but that a phase-out of coal is entirely possible. In a 2007 testimony before the Iowa Utilities Board, he stated that the United States has a large reservoir of coal, which makes it a resource that can be controlled through action by U.S. politicians, unlike oil which is controlled by other countries.[34] He and other climate scientists have called for coal phase out completely by the year 2030.[35]

Hansen has said that phasing out coal “is 80% of the solution to the global warming crisis.”[36] As pointed out in Ted Nace's Climate Hope, Hansen’s reasons for emphasizing coal were fourfold:

  • The amount of carbon remaining in the ground in oil and gas reserves is much smaller than the amount of carbon contained in coal reserves.[37]
  • "Second, coal is the most carbon intense of the fossil fuels. Producing a kilowatt-hour of electricity from coal produces about 2.4 pounds of carbon dioxide, while producing a kilowatt-hour of electricity from natural gas produces about 1 pound of carbon dioxide. While coal produces half of the electricity used in the United States, it is responsible for 80 percent of the carbon dioxide released by electric utilities."[38]
  • "Third, coal consumption is far more concentrated than the use of other fossil fuels. A mere six hundred large coal-burning power plants account for nearly all coal usage, in contrast to the tens of millions of cars, trucks, planes, homes, businesses, and factories that burn oil and gas. Thus, reducing emissions from coal is a far simpler task."[38]
  • "Fourth, production of oil and gas is primarily located in countries that American domestic energy policy has little or no ability to control. Any reduction in use by the United States might well be consumed by other countries. In contrast, our ability to control the consumption of coal is substantial, since the United States leads the rest of the world in the size of its coal reserves."[38]

Air pollution from coal-fired power plants

According to the Union of Concerned Scientists, in an average year, a typical coal plant (500 megawatts) generates the following amounts of air pollutants:[39]

  • 3.7 million tons of carbon dioxide (CO2), an amount equivalent to chopping down 161 million trees. CO2 pollution is the principal human cause of global warming and climate change.
  • 10,000 tons of sulfur dioxide (SO2), which causes acid rain and forms small airborne particles that can cause lung damage, heart disease, and other illnesses.
  • 10,200 tons of nitrogen oxides (NOx), equivalent to half a million late-model cars. NOx leads to formation of smog, which inflames lung tissue and increases susceptibility to respiratory illness.
  • 500 tons of small airborne particles, which can cause bronchitis, reductions in lung function, increased hospital and emergency room admissions, and premature death.[40]
  • 220 tons of hydrocarbons, which contribute to smog formation.
  • 720 tons of carbon monoxide (CO), which causes headaches and places additional stress on people with heart disease.
  • 170 pounds of mercury. 1/70th of a teaspoon of mercury deposited in a 25-acre lake can make the fish unsafe to eat. Mercury also causes learning disabilities, brain damage, and neurological disorders.[41]
  • 225 pounds of arsenic, which leads to cancer in 1 out of 100 people who drink water containing 50 parts per billion.
  • 114 pounds of lead, 4 pounds of cadmium, and other toxic heavy metals. These toxic metals can accumulate in human and animal tissue and cause serious health problems, including mental retardation, developmental disorders, and damage to the nervous system.[42]

Radioactivity and coal

Coal contains minor amounts of the radioactive elements, uranium and thorium. When coal is burnt, the fly ash contains uranium and thorium "at up to 10 times their original levels."[43]

Solid waste from coal-fired power plants

According to a New York Times analysis of EPA data, power plants are the nation’s biggest producer of toxic waste, surpassing industries like plastic, paint manufacturing, and chemical plants.[44]

Solid waste from a typical 500MW coal plant contains 120,000 tons of ash and 193,000 tons of coal sludge from the smokestack scrubber. In the U.S. more than 75 percent of this waste is disposed of in unlined, unmonitored landfills and surface impoundments, and can leach into and contaminate drinking water. Toxic substances in ash and sludge include arsenic, mercury, chromium, and cadmium.[45]

There is no federal regulation for the disposal of fly ash. A 2007 EPA report cited 67 cases in the United States of damage to ground or surface water from coal-combustion products.[46]

The Oak Ridge National Laboratory estimates that in an average year, a typical 1000 MW coal plant releases significant amounts of radioactive material, including 5.2 tons of uranium and 12.8 tons of thorium.[47]

Water Pollution from Coal

Coal mine reclamation site leaching acid mine runoff in KY. Photo courtesy of ilovemountains.org.

Acid mine drainage (AMD) refers to the outflow of acidic water from coal or metal mines, often abandoned ones where ore- or coal mining activities have exposed rocks containing the sulphur-bearing mineral pyrite. Pyrite reacts with air and water to form sulphuric acid and dissolved iron, and as water washes through mines, this compound forms a dilute acid, which can wash into nearby rivers and streams.[1] AMD discharges elevated concentrations of acidity, iron, manganese, aluminum, and sulfate into receiving streams and rivers, depleting the buffering ability of water by neutralizing carbonate and bicarbonate ions that form carbonic acid. Streams and rivers with low buffer capacity are not able to neutralize the acid load and consequently become acidic. An estimated 2,390 miles of streams in the Allegheny and Monongahela River Basins have been degraded by AMD to the point of not being able to support fish communities.[48]

The use of bagpipes and scrubbers to trap pollutants and toxins from power plant emissions - such as arsenic, aluminum, boron, chromium, manganese, nickel, or chemicals that have been linked to health risks - can leach into groundwater and waterways, contaminating drinking water supplies.[44]

As of January 2010, no federal regulations specifically govern the disposal of power plant discharges into waterways or landfills. Some regulators have used the Clean Water Act to try and limit pollution, but the law does not mandate limits on many dangerous chemicals in power plant waste, like arsenic and lead.[44]

According to a New York Times analysis of EPA records, 21 power plants in 10 states have dumped arsenic into rivers or other waters at concentrations as much as 18 times the federal drinking water standard. State officials sometimes place no limits on water discharges of arsenic, aluminum, boron, chromium, manganese, nickel or other chemicals that have been linked to health risks. Only one in 43 U.S. power plants must limit how much barium is dumped into nearby waterways, despite being commonly found in power plant waste and scrubber wastewater and linked to heart problems and disease. EPA records indicate power plant landfills and other disposal practices have polluted groundwater in more than a dozen states, while a 2007 EPA report suggested that people living near some power plant landfills faced a cancer risk 2,000 times higher than federal health standards.[44]

Power plants have often violated the Clean Water Act without paying fines or facing other penalties: ninety percent of 313 coal-fired power plants that violated the law since 2004 were not fined or otherwise sanctioned by federal or state regulators. And fines are often modest: Hatfield’s Ferry has violated the Clean Water Act 33 times since 2006, but has paid less than $26,000, even as the plant’s parent company earned $1.1 billion.[44]

According to the New York Times, after five states — including New York and New Jersey — sued Allegheny Energy to install scrubbers at one of its coal plants, the company began dumping tens of thousands of gallons of wastewater containing chemicals from the scrubbing process into the Monongahela River. The River provides drinking water to 350,000 people and flows into Pittsburgh.[44]

Water consumption from coal plants

Power generation has been estimated to be second only to agriculture in being the largest domestic user of water.[29] Water is used by thermoelectric generating facilities (coal, natural gas, and nuclear) to make electricity through converting the water into high-pressure steam to drive turbines. Once through this cycle, the steam is cooled and condensed back into water, with some technologies using water to cool the steam, increasing a plant's water usage. In coal plants, water is also used to clean and process the fuel itself. The U.S. Geological Survey estimates that thermoelectric plants withdrew 195 billion gallons of water per day in 2000, of which 136 billion gallons was fresh water.[29]

Integrated Gasification Combined Cycle (IGCC), which converts coal into synthetic gas or syngas to extract more energy, is being promoted as a path toward carbon capture and storage; however as of 2009 capturing carbon dioxide (CO2) reduces plant efficiency and increases water usage. An Electric Power Research Institute study found CO2 capture equipment decreased plant output by at least 25% and increases water consumption by approximately 23%.[49]

Thermal pollution from coal plants

Thermal pollution is the degradation of water quality by any process that changes ambient water temperature. A common cause of thermal pollution is the use of water as a coolant by power plants and industrial manufacturers. When water used as a coolant is returned to the natural environment at a higher temperature, the change in temperature impacts organisms by (a) decreasing oxygen supply, and (b) affecting ecosystem composition.[27]

When a power plant first opens or shuts down for repair or other causes, fish and other organisms adapted to particular temperature range can be killed by the abrupt rise in water temperature known as 'thermal shock': most aquatic organisms have developed enzyme systems that operate in only narrow ranges of temperature, and can be killed by sudden temperature changes that are beyond the tolerance limits of their metabolic systems.[27]

Coal mining

Coal mining also has a number of adverse effects on the environment:

  • the release of methane (CH4), a potent greenhouse gas estimated to account for 18% of the overall global warming effect triggered by human activities (CO2 is estimated to contribute 50%).[50]
  • the release of carbon monoxide (CO) from explosives, which pollutes the air and poses a health risk for mine workers.[6]
  • drastic alteration of the landscape, which can render an area unfit for other purposes, even after coal mine reclamation. The clearing of trees, plants, and topsoil from mining areas destroys forests and natural wildlife habitats. It also promotes soil erosion and flooding, and stirs up dust pollution that can lead to respiratory problems in nearby communities. In mountaintop removal mining, most common in the Appalachian region of the U.S., mountaintops are literally blown off to reach coal seams, with the waste products deposited into valleys below, causing permanent damage to the landscape and the local ecosystem. According to the Sierra Club, this practice has "damaged or destroyed approximately 1,200 miles of streams, disrupted drinking water supplies, flooded communities, eliminated forests, and destroyed wildlife habitat. Coal companies have created at least 6,800 fills to hold their mining wastes, and the government estimates that if this mining continues unabated in Appalachia it will destroy 1.4 million acres of land by 2020."[6]
  • water pollution, as sulfuric acid forms when coal is exposed to air and water, creating an acid run-off with heavy metals such as copper, lead, and mercury that can leech into streams, acidifying and polluting the water and killing fish, plants, and aquatic animals.[50] Seepage from coal sludge can also infect local water supplies.[6]
  • dust and coal particles stirred up during the mining process, as well as the soot released during coal transport, which can cause severe and potentially deadly respiratory problems.[6]

As of June 2010, no national limits exist on air pollution from coal mines. On June 17, 2010, in a petition presented to Environmental Protection Agency Administrator Lisa Jackson, a coalition of environmental groups called for new controls over coal mine air pollution. The petition states that coal mines should be held to the Clean Air Act standards in force for gravel mines, coal-fired power plants, coal processing plants, and other sources. The petition also calls on Jackson to adopt strict limits on other dangerous air pollutants released from coal mines, including methane, as well as particulate matter, nitrogen oxide gases, and volatile organic compounds — all toxic air pollutants under the Clean Air Act.[51]

Coal transport

The long-distance transport of coal can also result in occasional but significant environmental impacts. In April 2010, a bulk carrier transporting approximately 65,000 tonnes of coal from Gladstone Australia to China ran aground on the Great Barrier Reef. See Shen Neng 1 coal carrier collision with the Great Barrier Reef, Australia.

Cost of environmental damages from coal plants

2009 NAS report

A 2009 National Academy of Sciences report, Hidden Cost of Energy: Unpriced Consequences of Energy Production and Use, found that the external costs of coal from US coal-fired power plants add up to over $62 billion in environmental damages a year. These include damage done to crop and timber yields, to buildings and materials, and the toll coal takes on human health--including the cost of illness and premature deaths. The study examined 406 coal plants that collectively create about 95% of the nation's coal-burned electricity. As Bloomberg notes, the "aggregate damages associated with sulfur dioxide, nitrogen oxides and particulate matter emitted by the facilities amounted to $156 million on average per plant." These are costs not borne by coal and power companies. The study did not consider any potential damages done by greenhouse gas emissions.[52]

2011 Harvard report: external costs of coal up to $500 billion annually

A Feb. 2011 report, "Mining Coal, Mounting Costs: the Life Cycle Consequences of Coal," led by associate director of the Center for Health and the Global Environment at Harvard Medical School Dr. Paul Epstein, found that accounting for the full costs of coal would double or triple its price. The study, which was released in the Annals of the New York Academy of Sciences, tallied the economic, health and environmental costs associated with each stage in the life cycle of coal – extraction, transportation, processing, and combustion - and estimated those costs, which are borne by the public at large, to be between $175 billion and $500 billion dollars annually.[53]

In terms of human health, the report estimated $74.6 billion a year in public health burdens in Appalachian communities, with a majority of the impact resulting from increased healthcare costs, injury and death. Air pollutants from combustion accounted for $187.5 billion, mercury impacts as much as $29.3 billion, and climate contributions from combustion between $61.7 and $205.8 billion. The study discussed a number of other impacts that are not easily quantified, including effects of heavy metal toxins and carcinogens released into water supplies as part of coal mining and processing; the death and injury of workers mining coal; and the social impacts in mining communities.[53]

Table 1: Estimates of external costs of coal in cents/kWh of electricity (2008 US$)[54]

Type of impact Low Best High
Land disturbance 0.00 0.01 0.34
Methane emissions from mines 0.03 0.08 0.34
Public health burden in Appalachia 4.36 4.36 4.36
Fatalities due to coal transport 0.09 0.09 0.09
Air pollutants from combustion 3.23 9.31 9.31
Lost productivity from mercury emissions 0.01 0.10 0.48
Excess mental retardation from mercury emissions 0.00 0.02 0.19
Excess cardiovascular disease from mercury emissions 0.01 0.21 1.05
Climate damage from combustion emissions of CO2 and N2O 1.02 3.06 10.20
Climate damage from combustion emissions of black carbon 0.00 0.00 0.01
Subsidies 0.16 0.16 0.27
Abandoned mine lands 0.44 0.44 0.44
Total 9.36 17.84 26.89


The study concluded:

"Our comprehensive review finds that the best estimate for the total economically quantifiable costs, based on a conservative weighting of many of the study findings, amount to some $345.3 billion, adding close to 17.8¢/kWh of electricity generated from coal. The low estimate is $175 billion, or over 9¢/kWh, while the true monetizable costs could be as much as the upper bounds of $523.3 billion, adding close to 26.89¢/kWh. These and the more difficult to quantify externalities are borne by the general public." The average residential price of electricity at the time of the report is 12¢/kWh.[53]

Skeptical Science notes that when the coal externalities of the study are included in coal's price, it increases the levalized costs to approximately 28 cents per kWh, which is more than the 2009 U.S. Energy Information Administration cost of hydroelectric, wind (onshore and offshore), geothermal, biomass, nuclear, natural gas, and solar photovoltaics, and is on par with solar thermal, although the costs of solar thermal are falling.[55]

The study noted that its estimates did not include the full cost of coal:[53]

"Still these figures do not represent the full societal and environmental burden of coal. In quantifying the damages, we have omitted the impacts of toxic chemicals and heavy metals on ecological systems and diverse plants and animals; some ill-health endpoints (morbidity) aside from mortality related to air pollutants released through coal combustion that are still not captured; the direct risks and hazards posed by coal sludge, coal slurry, and coal waste impoundments; the full contributions of nitrogen deposition to eutrophication of fresh and coastal sea water; the prolonged impacts of acid rain and acid mine drainage; many of the long-term impacts on the physical and mental health of those living in coal-field regions and nearby MTR sites; some of the health impacts and climate forcing due to increased tropospheric ozone formation; and the full assessment of impacts due to an increasingly unstable climate."[53]

Resources

References

  1. 1.0 1.1 "Coal mining and the environment: Acid Mine Drainage" World Coal Institute, accessed June 2010.
  2. 2.0 2.1 "Green Coal?," Rachel's Environment & Health News, November 6, 2008.
  3. Partha Das Sharma,"Coal mining and pollution" Knol Website, July 2009
  4. Barbara Freese and Steve Clemmer, "Gambling with Coal: How New Climate Laws Will Make Future Coal Plants More Expensive," Union of Concerned Scientists, September 2006, page 2.
  5. "Black Carbon Implicated in Global Warming" Science daily, July 30, 2010.
  6. 6.0 6.1 6.2 6.3 6.4 "The Dirty Truth about Coal: Mining", Sierra Club, June 2007.
  7. Dan Cray (July 23, 2010). "Deep Underground, Miles of Hidden Wildfires Rage", Time Magazine. 
  8. Kristin Ohlson, "Earth On Fire" Discover Magazine, January 4, 2011.
  9. Sue Sturgis, "Coal's ticking timebomb: Could disaster strike a coal ash dump near you?," Institute for Southern Studies, January 2009
  10. "Analyzing why all landfills leak," Rachel's Environment & Health News, February 14, 1989.
  11. "EPA says all landfills leak, even those using best available liners," Rachel's Environment & Health News, August 10, 1987.
  12. James F. Fox and J. Elliott Campbell, "Terrestrial Carbon Disturbance from Mountaintop Mining Increases Lifecycle Emissions for Clean Coal," Environ. Sci. Technol., 2010, 44 (6), pp 2144–2149, February 8, 2010
  13. Ken Ward, Jr., "Important new study details mountaintop removal coal mining's huge carbon footprint," Coal Tattoo, March 17, 2010
  14. James F. Fox and J. Elliott Campbell, "Terrestrial Carbon Disturbance from Mountaintop Mining Increases Lifecycle Emissions for Clean Coal," Environ. Sci. Technol., 2010, 44 (6), pp 2144–2149, February 8, 2010
  15. Ken Ward, Jr., "Important new study details mountaintop removal coal mining's huge carbon footprint," Coal Tattoo, March 17, 2010
  16. Jeff Goodell, Big Coal: The Dirty Secret Behind America's Energy Future. New York, N.Y.: Houghton-Mifflin, 2006
  17. "Heavy Metals Naturally Present in Coal & Coal Sludge" Sludge Safety Project, accessed November 2009
  18. Eilene Toppin Ording,"Heavy Metals and Coal: Carbon Footprint Aside, Coal is not Environmentally Friendly" Suite 101, accessed November 2009
  19. “Mercury Emissions from Coal-Fired Power Plants: The Case for Regulatory Action,” Northeast States for Coordinated Air Use Management, October 2003.
  20. U.S. Environmental Protection Agency ,"Methane: sources and emissions," U.S. Environmental Protection Agency website, October 20th, 2006.
  21. "Key Issues & Mandates: Secure & Reliable Energy Supplies - Coal Becomes a 'Future Fuel'” NETL, accessed May 2010.
  22. Alan Lockwood, Kristen Welker-Hood, Molly Rauch, Barbara Gottlieb,"Coal's Assault on Human Health" Physicians for Social Responsibility Report, November 2009
  23. Clean Air Task Force,"Dirty Air, Dirty Power: Mortality and Health Damage Due to Air Pollution from Power Plants", June 2004
  24. Mara Hvistendahl, "Coal Ash is More Radioactive than Nuclear Waste", Scientific American, December 13, 2007.
  25. "Coal Mining and the Environment" World Coal Institute, accessed November 2009
  26. Sulfur dioxide, Tennessee Valley Authority, accessed April 2008.
  27. 27.0 27.1 27.2 "Thermal Pollution" Pollution Issues, accessed November 2009
  28. "Burning waste coal is much dirtier than burning coal," Energy Justice Network, accessed 1/09
  29. 29.0 29.1 29.2 Lance Frazer, "Low water consumption: a new goal for coal" Environmental Health Perspectives, April, 2004
  30. U.S. Environmental Protection Agency (EPA), “Inventory of US Greenhouse Gas Emissions and Sinks: 1990-2004,” April 2006.
  31. Barbara Freese and Steve Clemmer, "Gambling with Coal: How New Climate Laws Will Make Future Coal Plants More Expensive," Union of Concerned Scientists, September 2006, page 2.
  32. Testimony of Joseph Romm before Congress, September 5, 2007.
  33. "Carbon Dioxide Emissions from the Generation of Electric Power in the United States," U.S. Energy Information Agency, July 2000
  34. 34.0 34.1 "State of Iowa, Before the Iowa Utilities Board: Direct Testimony of James E. Hansen" Columbia, November 5, 2007
  35. "Target Atmospheric CO2: Where Should Humanity Aim?" Columbia, April 7, 2008
  36. Letter from James Hansen to Nevada governor Gibbons, April 14, 2008, at www.columbia.edu/~jeh1/
  37. Historical Fossil Fuel Emissions and Remaining Reserves. Source: Adapted from James Hansen et al., “Target Atmospheric CO2: Where Should Humanity Aim?” Open Atmospheric Science Journal (2008): page 11. Estimates for remaining oil, gas, and coal reserves are from Intergovernmental Panel on Climate Change, Climate Change 2001: Mitigation, B. Metz et al., eds. (New York: Cambridge University Press, 2001).
  38. 38.0 38.1 38.2 Ted Nace, Climate Hope, Chapter 1, published 2010
  39. "Coal Power: Air Pollution," Union of Concerned Scientists, accessed August 2008
  40. Particulate Pollution, NRDC, accessed April 2008.
  41. Air Pollution in the Mountains, Appalachian Voices, accessed April 2008.
  42. Public Benefits of Renewable Energy Use, Union of Concerned Scientists, 1999.
  43. Mara Hvistendahl, "Coal Ash is More Radioactive than Nuclear Waste", Scientific American, December 13, 2007.
  44. 44.0 44.1 44.2 44.3 44.4 44.5 Charles Duhigg,"Cleansing the Air at the Expense of Waterways" New York Times, October 12, 2009
  45. "Coal Power: Wastes Generated," Union of Concerned Scientists, accessed August 2008
  46. "Indiana town to Chesapeake: Fly-ash battle won’t be easy," Virginia Pilot, October 17, 2008.
  47. Coal Combustion: Nuclear Resource or Danger, ORNL Review Vol. 26, Nos. 3&4, 1993.
  48. James I. Sams III and Kevin M. Beer, "Effects of Coal-Mine Drainage on Stream Water Quality in the Allegheny and Monongahela River Basins—Sulfate Transport and Trends" U.S. Department of the Interior Water-Resources Investigations Report 99-4208, 2000.
  49. “’Clean Coal’ Power Plants (IGCC)" EnergyJustice.net Report, Oct. 31, 2007
  50. 50.0 50.1 Environmental Impacts of Coal Mining, World Coal Institute, accessed April 2008.
  51. "Coal mine air pollution targeted" WY Business report, June 18, 2010.
  52. Brian Merchant, "Coal Plants Do $62 Billion of Damage a Year to US Environment Treehugger, Oct. 19, 2009.
  53. 53.0 53.1 53.2 53.3 53.4 "Life-cycle study: Accounting for total harm from coal would add 'close to 17.8¢/kWh of electricity generated'” Climate Progress, Feb. 16, 2011.
  54. Paul R. Epstein et al, "Mining Coal, Mounting Costs: the Life Cycle Consequences of Coal," Annals of the New York Academy of Sciences, 1219 (2011) p. 92
  55. "The True Cost of Coal Power" Skeptical Science, March 18, 2011.

Related SourceWatch articles

External links