, a 1,580
MW coal power station near
Laughlin, Nevada, out of service since 2005 due to environmental restrictions Thermal power plants are one of the main artificial sources of producing toxic gases and
particulate matter. Fossil fuel power plants cause the emission of pollutants such as , SOx, , CO, PM, organic gases and polycyclic aromatic hydrocarbons. World organizations and international agencies, like the IEA, are concerned about the
environmental impact of burning fossil fuels, and coal in particular. The combustion of coal contributes the most to
acid rain and
air pollution, and has been connected with
global warming. Due to the chemical composition of coal there are difficulties in removing impurities from the solid fuel prior to its combustion. Modern day coal power plants pollute less than older designs due to new "
scrubber" technologies that filter the exhaust air in smoke stacks. However, emission levels of various pollutants are still on average several times greater than natural gas power plants and the scrubbers transfer the captured pollutants to wastewater, which still requires treatment in order to avoid
pollution of receiving water bodies. In these modern designs, pollution from coal-fired power plants comes from the emission of gases such as carbon dioxide,
nitrogen oxides, and
sulfur dioxide into the air, as well a significant volume of wastewater which may contain
lead,
mercury,
cadmium and
chromium, as well as
arsenic,
selenium and
nitrogen compounds (
nitrates and
nitrites). Acid rain is caused by the emission of
nitrogen oxides and
sulfur dioxide. These gases may be only mildly acidic themselves, yet when they react with the atmosphere, they create acidic compounds such as
sulfurous acid,
nitric acid and
sulfuric acid which fall as rain, hence the term acid rain. In Europe and the US, stricter emission laws and decline in heavy industries have reduced the environmental hazards associated with this problem, leading to lower emissions after their peak in 1960s. In 2008, the
European Environment Agency (EEA) documented fuel-dependent emission factors based on actual emissions from power plants in the
European Union.
Carbon dioxide in
Taiwan, the world's largest carbon dioxide emitter Electricity generation using carbon-based fuels is responsible for a large fraction of carbon dioxide (CO2) emissions worldwide and for 34% of U.S. man-made carbon dioxide emissions in 2010. In the U.S. 70% of electricity is generated by combustion of fossil fuels. Coal contains more carbon than oil or natural gas fossil fuels, resulting in greater volumes of carbon dioxide emissions per unit of electricity generated. In 2010, coal contributed about 81% of CO2 emissions from generation and contributed about 45% of the electricity generated in the United States. In 2000, the carbon intensity (CO2 emissions) of U.S. coal thermal combustion was 2249 lbs/MWh (1,029 kg/MWh) while the carbon intensity of U.S. oil thermal generation was 1672 lb/MWh (758 kg/MWh or 211 kg/
GJ) and the carbon intensity of U.S. natural gas thermal production was 1135 lb/MWh (515 kg/MWh or 143 kg/GJ). The
Intergovernmental Panel on Climate Change (
IPCC) reports that increased quantities of the
greenhouse gas carbon dioxide within the atmosphere will "very likely" lead to higher average temperatures on a global scale (
global warming). Concerns regarding the potential for such warming to change the global climate prompted IPCC recommendations calling for large cuts to CO2 emissions worldwide. Emissions can be reduced with higher combustion temperatures, yielding more efficient production of electricity within the cycle. the price of emitting CO2 to the atmosphere is much lower than the cost of adding
carbon capture and storage (CCS) to fossil fuel power stations, so owners have not done so. CO2 emissions =
capacity ×
capacity factor ×
heat rate ×
emission intensity × time where "capacity" is the "
nameplate capacity" or the maximum allowed output of the plant, "
capacity factor" or "load factor" is a measure of the amount of power that a plant produces compared with the amount it would produce if operated at its rated capacity nonstop,
heat rate is thermal energy in/electrical energy out, emission intensity (also called
emission factor) is the CO2 emitted per unit of heat generated for a particular fuel. As an example, a new 1500 MW supercritical lignite-fueled power station running on average at half its capacity might have annual CO2 emissions estimated as: = 1500MW × 0.5 × 100/40 × 101000 kg/TJ × 1year = 1500MJ/s × 0.5 × 2.5 × 0.101 kg/MJ × 365x24x60x60s = 1.5×103 × 5×10−1 × 2.5 × 1.01−1 × 3.1536×107 kg = 59.7 ×103-1-1+7 kg = 5.97 Mt Thus the example power station is estimated to emit about 6 megatonnes of carbon dioxide each year. The results of similar estimations are mapped by organisations such as
Global Energy Monitor,
Carbon Tracker and ElectricityMap. Alternatively it may be possible to measure emissions (perhaps indirectly via another gas) from satellite observations.
Particulate matter Another problem related to coal combustion is the emission of
particulates that have a serious impact on public health. Power plants remove particulate from the flue gas with the use of a
bag house or
electrostatic precipitator. Several newer plants that burn coal use a different process,
Integrated Gasification Combined Cycle in which
synthesis gas is made out of a reaction between coal and water. The synthesis gas is processed to remove most pollutants and then used initially to power gas turbines. Then the hot exhaust gases from the gas turbines are used to generate steam to power a steam turbine. The pollution levels of such plants are drastically lower than those of "classic" coal power plants. Particulate matter from coal-fired plants can be harmful and have negative health impacts. Studies have shown that exposure to particulate matter is related to an increase of respiratory and cardiac mortality. Particulate matter can irritate small airways in the lungs, which can lead to increased problems with asthma, chronic bronchitis, airway obstruction, and gas exchange. Coal fly ash is what remains after the coal has been combusted, so it consists of the incombustible materials that are found in the coal. The size and chemical composition of these particles affects the impacts on human health.
Wastewater Fossil-fuel power stations, particularly coal-fired plants, are a major source of
industrial wastewater. Wastewater streams include flue-gas desulfurization, fly ash, bottom ash and flue gas mercury control. Plants with air pollution controls such as wet scrubbers typically transfer the captured pollutants to the wastewater stream.
Radioactive trace elements Coal is a sedimentary rock formed primarily from accumulated plant matter, and it includes many inorganic minerals and elements which were deposited along with organic material during its formation. As the rest of the Earth's
crust, coal also contains low levels of
uranium,
thorium, and other naturally occurring
radioactive isotopes whose release into the environment leads to
radioactive contamination. While these substances are present as very small trace impurities, enough coal is burned that significant amounts of these substances are released. A 1,000 MW coal-burning power plant could have an uncontrolled release of as much as 5.2 metric tons per year of uranium (containing of
uranium-235) and 12.8 metric tons per year of thorium. In comparison, a 1,000 MW nuclear plant will generate about 30 metric tons of high-level radioactive solid packed waste per year. It is estimated that during 1982, US coal burning released 155 times as much uncontrolled radioactivity into the atmosphere as the
Three Mile Island incident. The collective radioactivity resulting from all coal burning worldwide between 1937 and 2040 is estimated to be 2,700,000 curies or 0.101 EBq. of radioactivity, a value one order of magnitude above this value for total emissions from all coal burned within a century, while the iodine-131, the major radioactive substance which comes out in accident situations, has a half-life of just 8 days.
Water and air contamination by coal ash A study released in August 2010 that examined state pollution data in the United States by the organizations
Environmental Integrity Project, the
Sierra Club and
Earthjustice found that coal ash produced by coal-fired power plants dumped at sites across 21 U.S. states has contaminated ground water with toxic elements. The contaminants including the poisons
arsenic and
lead. The study concluded that the problem of coal ash-caused water contamination is even more extensive in the United States than has been estimated. The study brought to 137 the number of ground water sites across the United States that are contaminated by power plant-produced coal ash. Arsenic has been shown to cause
skin cancer,
bladder cancer and
lung cancer, and lead damages the
nervous system. Coal ash contaminants are also linked to respiratory diseases and other health and developmental problems, and have disrupted local aquatic life. ==Conversion of fossil fuel power plants==