{"id":2427,"date":"2016-06-07T22:30:58","date_gmt":"2016-06-07T22:30:58","guid":{"rendered":"https:\/\/courses.lumenlearning.com\/geologyxwaymakerxmaster\/?post_type=chapter&p=2427"},"modified":"2025-10-13T17:08:02","modified_gmt":"2025-10-13T17:08:02","slug":"reading-coal-2","status":"publish","type":"chapter","link":"https:\/\/courses.lumenlearning.com\/geo\/chapter\/reading-coal-2\/","title":{"raw":"Reading: Coal","rendered":"Reading: Coal"},"content":{"raw":"[caption id=\"attachment_1038\" align=\"alignright\" width=\"300\"]\"a Figure 1. Bituminous coal[\/caption]\r\n\r\nCoal<\/b> (from the Old English term col<\/i>, which has meant \"mineral of fossilized carbon\" since the thirteent\u00a0century)is a combustible black or brownish-black sedimentary rock usually occurring in rock strata in layers or veins called coal beds<\/b> or coal seams<\/b>. The harder forms, such as anthracite coal, can be regarded as metamorphic rock because of later exposure to elevated temperature and pressure. Coal is composed primarily of carbon along with variable quantities of other elements, chiefly hydrogen, sulfur, oxygen, and nitrogen.\r\n\r\nThroughout history, coal has been used as an energy resource, primarily burned for the production of electricity and\/or heat, and is also used for industrial purposes, such as refining metals. A fossil fuel, coal forms when dead plant matter is converted into peat, which in turn is converted into\u00a0lignite, then sub-bituminous coal, after that bituminous coal, and lastly anthracite. This involves biological and geological processes that take place over a long period. The United States Energy Information Administration estimates coal reserves at 948\u00d7109<\/sup><\/span> short tons (860 Gt).\u00a0One estimate for\u00a0resources is 18 000 Gt.\r\n\r\nCoal is the largest source of energy for the generation of electricity worldwide, as well as one of the largest worldwide anthropogenic sources ofcarbon dioxide releases. In 1999, world gross carbon dioxide emissions from coal usage were 8,666 million tonnes of carbon dioxide.\u00a0In 2011, world gross emissions from coal usage were 14,416 million tonnes.\u00a0Coal-fired electric power generation emits around 2,000 pounds of carbon dioxide for every megawatt-hour generated, which is almost double the approximately 1100 pounds of carbon dioxide released by a natural gas-fired electric plant per megawatt-hour generated. Because of this higher carbon efficiency of natural gas generation, as the market in the United States has changed to reduce coal and increase natural gas generation, carbon dioxide emissions have fallen. Those measured in the first quarter of 2012 were the lowest of any recorded for the first quarter of any year since 1992\u00a0In 2013, the head of the UN climate agency advised that most of the world's coal reserves should be left in the ground to avoid catastrophic global warming.\r\n\r\nCoal is extracted from the ground by coal mining, either underground by shaft mining, or at ground level by open pit mining extraction. Since 1983 the world top coal producer has been China.\u00a0In 2011 China produced 3,520 million tonnes of coal \u2013 49.5% of 7,695 million tonnes world coal production. In 2011 other large producers were United States (993 million tonnes), India (589), European Union (576) and Australia (416).\u00a0In 2010 the largest exporters were Australia with 328 million tonnes (27.1% of world coal export) and Indonesia with 316 million tonnes (26.1%),\u00a0while the largest importers were Japan with 207 million tonnes (17.5% of world coal import), China with 195 million tonnes (16.6%) and South Korea with 126 million tonnes (10.7%).\r\n

Formation<\/span><\/h2>\r\n[caption id=\"attachment_1039\" align=\"alignright\" width=\"399\"]\"A Figure 2. Coastal exposure of the Point Aconi Seam (Nova Scotia)[\/caption]\r\n\r\nAt various times in the geologic past, the Earth had dense forests in low-lying wetland areas. Due to natural processes such as flooding, these forests were buried underneath soil. As more and more soil deposited over them, they were compressed. The temperature also rose as they sank deeper and deeper. As the process continued the plant matter was protected from biodegradation and oxidation, usually by mud or acidic water. This trapped the carbon in immense peat bogs that were eventually covered and deeply buried by sediments. Under high pressure and high temperature, dead vegetation was slowly converted to coal. As coal contains mainly carbon, the conversion of dead vegetation into coal is called carbonization.\r\n\r\nThe wide, shallow seas of the Carboniferous Period provided ideal conditions for coal formation, although coal is known from most geological periods. The exception is the coal gap in the Permian\u2013Triassic extinction event, where coal is rare. Coal is known from Precambrian strata, which predate land plants\u2014this coal is presumed to have originated from residues of algae.\r\n

Ranks<\/span><\/h2>\r\nAs geological processes apply pressure to dead biotic material over time, under suitable conditions, its metamorphic grade increases successively into:\r\n
    \r\n \t
  • Peat<\/strong>, considered to be a precursor of coal, has industrial importance as a fuel in some regions, for example, Ireland and Finland. In its dehydrated form, peat is a highly effective absorbent for fuel and oil spills on land and water. It is also used as a conditioner for soil to make it more able to retain and slowly release water.<\/li>\r\n \t
  • Lignite<\/strong>, or brown coal, is the lowest rank of coal and used almost exclusively as fuel for electric power generation. Jet, a compact form of lignite, is sometimes polished and has been used as an ornamental stone since the Upper Palaeolithic.<\/li>\r\n \t
  • Sub-bituminous coal<\/strong>, whose properties range from those of lignite to those of bituminous coal, is used primarily as fuel for steam-electric power generation and is an important source of light aromatic hydrocarbons for the chemical synthesis industry.<\/li>\r\n \t
  • Bituminous coal<\/strong> is a dense sedimentary rock, usually black, but sometimes dark brown, often with well-defined bands of bright and dull material; it is used primarily as fuel in steam-electric power generation, with substantial quantities used for heat and power applications in manufacturing and to make\u00a0coke.<\/li>\r\n \t
  • \"Steam coal<\/strong>\" is a grade between bituminous coal and anthracite, once widely used as a fuel for steam locomotives. In this specialized use, it is sometimes known as \"sea-coal\" in the United States.\u00a0Small steam coal (dry small steam nuts or DSSN) was used as a fuel for domestic water heating.<\/li>\r\n \t
  • Anthracite<\/strong>, the highest rank of coal, is a harder, glossy black coal used primarily for residential and commercial space heating. It may be divided further into metamorphically altered bituminous coal and \"petrified oil,\" as from the deposits in Pennsylvania.<\/li>\r\n \t
  • Graphite<\/strong>, technically the highest rank, is difficult to ignite and is not commonly used as fuel\u2014it is mostly used in pencils and, when powdered, as a\u00a0lubricant.<\/li>\r\n<\/ul>\r\nThe classification of coal is generally based on the content of volatiles. However, the exact classification varies between countries. According to the German classification, coal is classified as follows:\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n\r\n
    German Classification<\/th>\r\nEnglish Designation<\/th>\r\nVolatiles\u00a0%<\/th>\r\nC Carbon\u00a0%<\/th>\r\nH Hydrogen\u00a0%<\/th>\r\nO Oxygen\u00a0%<\/th>\r\nS Sulfur\u00a0%<\/th>\r\nHeat content kJ\/kg<\/th>\r\n<\/tr>\r\n
    Braunkohle<\/i><\/td>\r\nLignite (brown coal)<\/td>\r\n45\u201365<\/td>\r\n60\u201375<\/td>\r\n6.0\u20135.8<\/td>\r\n34-17<\/td>\r\n0.5-3<\/td>\r\n<28,470<\/td>\r\n<\/tr>\r\n
    Flammkohle<\/i><\/td>\r\nFlame coal<\/td>\r\n40-45<\/td>\r\n75-82<\/td>\r\n6.0-5.8<\/td>\r\n>9.8<\/td>\r\n~1<\/td>\r\n<32,870<\/td>\r\n<\/tr>\r\n
    Gasflammkohle<\/i><\/td>\r\nGas flame coal<\/td>\r\n35-40<\/td>\r\n82-85<\/td>\r\n5.8-5.6<\/td>\r\n9.8-7.3<\/td>\r\n~1<\/td>\r\n<33,910<\/td>\r\n<\/tr>\r\n
    Gaskohle<\/i><\/td>\r\nGas coal<\/td>\r\n28-35<\/td>\r\n85-87.5<\/td>\r\n5.6-5.0<\/td>\r\n7.3-4.5<\/td>\r\n~1<\/td>\r\n<34,960<\/td>\r\n<\/tr>\r\n
    Fettkohle<\/i><\/td>\r\nFat coal<\/td>\r\n19-28<\/td>\r\n87.5-89.5<\/td>\r\n5.0-4.5<\/td>\r\n4.5-3.2<\/td>\r\n~1<\/td>\r\n<35,380<\/td>\r\n<\/tr>\r\n
    Esskohle<\/i><\/td>\r\nForge coal<\/td>\r\n14-19<\/td>\r\n89.5-90.5<\/td>\r\n4.5-4.0<\/td>\r\n3.2-2.8<\/td>\r\n~1<\/td>\r\n<35,380<\/td>\r\n<\/tr>\r\n
    Magerkohle<\/i><\/td>\r\nNonbaking coal<\/td>\r\n10-14<\/td>\r\n90.5-91.5<\/td>\r\n4.0-3.75<\/td>\r\n2.8-3.5<\/td>\r\n~1<\/td>\r\n35,380<\/td>\r\n<\/tr>\r\n
    Anthrazit<\/i><\/td>\r\nAnthracite<\/td>\r\n7-12<\/td>\r\n>91.5<\/td>\r\n<3.75<\/td>\r\n<2.5<\/td>\r\n~1<\/td>\r\n<35,300<\/td>\r\n<\/tr>\r\n
    Note, the percentages are percent by mass of the indicated elements<\/th>\r\n<\/tr>\r\n<\/tbody>\r\n<\/table>\r\nThe middle six grades in the table represent a progressive transition from the English-language sub-bituminous to bituminous coal, while the last class is an approximate equivalent to anthracite, but more inclusive (US anthracite has < 6% volatiles).\r\n\r\nCannel coal (sometimes called \"candle coal\") is a variety of fine-grained, high-rank coal with significant hydrogen content. It consists primarily of \"exinite\" macerals, now termed \"liptinite.\"\r\n

    Hilt's law<\/span><\/h3>\r\nHilt's law is a geological term that states that, in a small area, the deeper the coal, the higher its rank (grade). The law holds true if the thermal gradient is entirely vertical, but metamorphism may cause lateral changes of rank, irrespective of depth.\r\n

    Content<\/span><\/h2>\r\n\r\n\r\n\r\n\r\n\r\n
    Average content<\/caption>\r\n
    Substance<\/th>\r\nContent<\/th>\r\n<\/tr>\r\n
    Mercury (Hg)<\/td>\r\n0.10\u00b10.01\u00a0ppm<\/span><\/td>\r\n<\/tr>\r\n
    Arsenic (As)<\/td>\r\n1.4 \u2013 71 ppm<\/span><\/td>\r\n<\/tr>\r\n
    Selenium (Se)<\/td>\r\n3 ppm<\/span><\/td>\r\n<\/tr>\r\n<\/tbody>\r\n<\/table>\r\n

    Uses Today<\/span><\/h2>\r\n

    Coal as Fuel<\/span><\/h3>\r\n[caption id=\"attachment_1040\" align=\"alignright\" width=\"350\"]\"power Figure 3. Castle Gate Power Plant near Helper, Utah, USA[\/caption]\r\n\r\nCoal is primarily used as a solid fuel to produce electricity and heat through combustion. World coal consumption was about 7.25 billion tonnes in 2010\u00a0<\/span>(7.99 billion short tons) and is expected to increase 48% to 9.05 billion tonnes (9.98 billion short tons) by 2030.\r\n\r\nChina produced 3.47 billion tonnes (3.83 billion short tons) in 2011. India produced about 578 million tonnes (637.1 million short tons) in 2011. 68.7% of China's electricity comes from coal. The USA consumed about 13% of the world total in 2010, i.e. 951 million tonnes (1.05 billion short tons), using 93% of it for generation of electricity.\u00a046% of total power generated in the USA was done using coal.\r\n\r\n[caption id=\"attachment_1042\" align=\"alignright\" width=\"350\"]\"Train Figure 4. Coal rail cars[\/caption]\r\n\r\nWhen coal is used for electricity generation, it is usually pulverized and then combusted (burned) in a furnace with a boiler.\u00a0The furnace heat converts boiler water to steam, which is then used to spin turbines which turn generators and create electricity.\u00a0The thermodynamic efficiency of this process has been improved over time; some older coal-fired power stations have thermal efficiencies in the vicinity of 25%\u00a0whereas the newest supercritical and \"ultra-supercritical\" steam cycle turbines, operating at temperatures over 600\u00a0\u00b0C and pressures over 27 MPa (over 3900 psi), can practically achieve thermal efficiencies in excess of 45% (LHV basis) using anthracite fuel,\u00a0or around 43% (LHV basis) even when using lower-grade lignite fuel.\u00a0<\/span>Further thermal efficiency improvements are also achievable by improved pre-drying (especially relevant with high-moisture fuel such as lignite or biomass) and cooling technologies.\r\n\r\nAn alternative approach of using coal for electricity generation with improved efficiency is the integrated gasification combined cycle (IGCC) power plant. Instead of pulverizing the coal and burning it directly as fuel in the steam-generating boiler, the coal can be first gasified (see coal gasification) to create\u00a0syngas, which is burned in a gas turbine to produce electricity (just like natural gas is burned in a turbine). Hot exhaust gases from the turbine are used to raise steam in a heat recovery steam generator which powers a supplemental steam turbine. Thermal efficiencies of current IGCC power plants range from 39-42%\u00a0(HHV basis) or ~42-45% (LHV basis) for bituminous coal and assuming utilization of mainstream gasification technologies (Shell, GE Gasifier, CB&I). IGCC power plants outperform conventional pulverized coal-fueled plants in terms of pollutant emissions, and allow for relatively easy carbon capture.\r\n\r\nAt least 40% of the world's electricity comes from coal,\u00a0and in 2012, about one-third of the United States' electricity came from coal, down from approximately 49% in 2008.\u00a0As of 2012 in the United States, use of coal to generate electricity was declining, as plentiful supplies of natural gas obtained by hydraulic fracturing of tight shale formations became available at low prices.\r\n\r\nIn Denmark, a net electric efficiency of > 47% has been obtained at the coal-fired Nordjyllandsv\u00e6rket CHP Plant and an overall plant efficiency of up to 91% with cogeneration of electricity and district heating.\u00a0The multifuel-fired Aved\u00f8rev\u00e6rket CHP Plant just outside Copenhagen can achieve a net electric efficiency as high as 49%. The overall plant efficiency with cogeneration of electricity and district heating can reach as much as 94%.\r\n\r\nAn alternative form of coal combustion is as coal-water slurry fuel (CWS), which was developed in the Soviet Union. CWS significantly reduces emissions, improving the heating value of coal.\u00a0Other ways to use coal are combined heat and power cogeneration and an MHD topping cycle.\r\n\r\nThe total known deposits recoverable by current technologies, including highly polluting, low-energy content types of coal (i.e., lignite, bituminous), is sufficient for many years.\u00a0However, consumption is increasing and maximal production could be reached within decades (see world coal reserves, below). On the other hand much may have to be left in the ground to avoid climate change.\r\n

    Gasification<\/span><\/h3>\r\nCoal gasification can be used to produce syngas, a mixture of carbon monoxide (CO) and hydrogen (H2<\/sub>) gas. Often syngas is used to fire gas turbines to produce electricity, but the versatility of syngas also allows it to be converted into transportation fuels, such as gasoline and diesel, through the Fischer-Tropsch process; alternatively, syngas can be converted into methanol, which can be blended into fuel directly or converted to gasoline via the methanol to gasoline process.[59]<\/sup> Gasification combined with Fischer-Tropsch technology is currently used by the Sasol chemical company of South Africa to make motor vehicle fuels from coal and natural gas. Alternatively, the hydrogen obtained from gasification can be used for various purposes, such as powering ahydrogen economy, making ammonia, or upgrading fossil fuels.\r\n\r\nDuring gasification, the coal is mixed with oxygen and steam while also being heated and pressurized. During the reaction, oxygen and water molecules oxidize the coal into carbon monoxide (CO), while also releasing hydrogen gas (H2<\/sub>). This process has been conducted in both underground coal mines and in the production of town gas.\r\n
    \r\n \t
    C (as Coal<\/i>) + O2<\/sub> + H2<\/sub>O \u2192 H2<\/sub> + CO<\/dd>\r\n<\/dl>\r\nIf the refiner wants to produce gasoline, the syngas is collected at this state and routed into a Fischer-Tropsch reaction. If hydrogen is the desired end-product, however, the syngas is fed into thewater gas shift reaction, where more hydrogen is liberated.\r\n
    \r\n \t
    CO + H2<\/sub>O \u2192 CO2<\/sub> + H2<\/sub><\/dd>\r\n<\/dl>\r\nIn the past, coal was converted to make coal gas (town gas), which was piped to customers to burn for illumination, heating, and cooking.\r\n

    Liquefaction<\/span><\/h3>\r\nCoal can also be converted into synthetic fuels equivalent to gasoline or diesel by several different direct processes (which do not intrinsically require gasification or indirect conversion).\u00a0In the direct liquefaction processes, the coal is either hydrogenated or carbonized. Hydrogenation processes are the Bergius process,\u00a0the SRC-I and SRC-II (Solvent Refined Coal) processes, the NUS Corporation hydrogenation process\u00a0and several other single-stage and two-stage processes.\u00a0In the process of low-temperature carbonization, coal is coked at temperatures between 360 and 750\u00a0\u00b0C (680 and 1,380\u00a0\u00b0F). These temperatures optimize the production of coal tars richer in lighter hydrocarbons than normal coal tar. The coal tar is then further processed into fuels. An overview of coal liquefaction and its future potential is available.\r\n\r\nCoal liquefaction methods involve carbon dioxide (CO2<\/sub>) emissions in the conversion process. If coal liquefaction is done without employing either carbon capture and storage (CCS) technologies or biomass blending, the result is lifecycle greenhouse gas footprints that are generally greater than those released in the extraction and refinement of liquid fuel production from crude oil. If CCS technologies are employed, reductions of 5\u201312% can be achieved in Coal to Liquid (CTL) plants and up to a 75% reduction is achievable when co-gasifying coal with commercially demonstrated levels of biomass (30% biomass by weight) in coal\/biomass-to-liquids plants.\u00a0For future synthetic fuel projects, carbon dioxide sequestration is proposed to avoid releasing CO2<\/sub> into the atmosphere. Sequestration adds to the cost of production.\r\n

    Refined Coal<\/span><\/h3>\r\nRefined coal is the product of a coal-upgrading technology that removes moisture and certain pollutants from lower-rank coals such as sub-bituminous and lignite (brown) coals. It is one form of several precombustion treatments and processes for coal that alter coal's characteristics before it is burned. The goals of precombustion coal technologies are to increase efficiency and reduce emissions when the coal is burned. Depending on the situation, precombustion technology can be used in place of or as a supplement to postcombustion technologies to control emissions from coal-fueled boilers.\r\n

    Industrial Processes\u00a0<\/span><\/h3>\r\nFinely ground bituminous coal, known in this application as sea coal, is a constituent of foundry sand. While the molten metal is in the mould, the coal burns slowly, releasing reducing gases at pressure, and so preventing the metal from penetrating the pores of the sand. It is also contained in \"mould wash,\" a paste or liquid with the same function applied to the mould before casting.\u00a0<\/span>Sea coal can be mixed with the clay lining (the \"bod\") used for the bottom of a cupola furnace. When heated, the coal decomposes and the bod becomes slightly friable, easing the process of breaking open holes for tapping the molten metal.\r\n

    Production of Chemicals<\/span><\/h3>\r\nCoal is an important feedstock in production of a wide range of chemical fertilizers and other chemical products. The main route to these products is coal gasification to produce syngas. Primary chemicals that are produced directly from the syngas include methanol, hydrogen and carbon monoxide, which are the chemical building blocks from which a whole spectrum of derivative chemicals are manufactured, including olefins, acetic acid, formaldehyde, ammonia,urea and others. The versatility of syngas as a precursor to primary chemicals and high-value derivative products provides the option of using relatively inexpensive coal to produce a wide range of valuable commodities.\r\n\r\nHistorically, production of chemicals from coal has been used since the 1950s and has become established in the market. According to the 2010 Worldwide Gasification Database,\u00a0a survey of current and planned gasifiers, from 2004 to 2007 chemical production increased its gasification product share from 37% to 45%. From 2008 to 2010, 22% of new gasifier additions were to be for chemical production.\r\n\r\nBecause the slate of chemical products that can be made via coal gasification can in general also use feedstocks derived from natural gas and petroleum, the chemical industry tends to use whatever feedstocks are most cost-effective. Therefore, interest in using coal tends to increase for higher oil and natural gas prices and during periods of high global economic growth that may strain oil and gas production. Also, production of chemicals from coal is of much higher interest in countries like South Africa, China, India and the United States where there are abundant coal resources. The abundance of coal combined with lack of natural gas resources in China is strong inducement for the coal to chemicals industry pursued there. In the United States, the best example of the industry is Eastman Chemical Company which has been successfully operating a coal-to-chemicals plant at its Kingsport, Tennessee, site since 1983. Similarly, Sasol has built and operated coal-to-chemicals facilities in South Africa.\r\n\r\nCoal to chemical processes do require substantial quantities of water. As of 2013 much of the coal to chemical production was in the People's Republic of China\u00a0where environmental regulation and water management\u00a0was weak.\r\n

    World Coal Reserves<\/span><\/h3>\r\nThe 948 billion short tons of recoverable coal reserves estimated by the Energy Information Administration are equal to about 4,196 BBOE (billion barrels of oil equivalent).\u00a0The amount of coal burned during 2007 was estimated at 7.075 billion short tons, or 133.179 quadrillion BTU's.\u00a0This is an average of 18.8 million BTU per short ton. In terms of heat content, this is about 57,000,000 barrels (9,100,000\u00a0m3<\/sup>) of oil equivalent per day. By comparison in 2007, natural gas provided 51,000,000 barrels (8,100,000\u00a0m3<\/sup>) of oil equivalent per day, while oil provided 85,800,000 barrels (13,640,000\u00a0m3<\/sup>) per day.\r\n\r\n[caption id=\"attachment_1044\" align=\"alignright\" width=\"350\"]\"Coal Figure 5. A coal mine in Wyoming, United States. The United States has the world's largest coal reserves.[\/caption]\r\n\r\nBritish Petroleum, in its 2007 report, estimated at 2006 end that there were 147 years reserves-to-production ratio based on proven<\/i> coal reserves worldwide. This figure only includes reserves classified as \"proven\"; exploration drilling programs by mining companies, particularly in under-explored areas, are continually providing new reserves. In many cases, companies are aware of coal deposits that have not been sufficiently drilled to qualify as \"proven.\" However, some nations haven't updated their information and assume reserves remain at the same levels even with withdrawals.\r\n\r\nOf the three fossil fuels, coal has the most widely distributed reserves; coal is mined in over 100 countries, and on all continents except Antarctica. The largest reserves are found in the United States, Russia, China, Australia and India.","rendered":"
    \"a<\/p>\n

    Figure 1. Bituminous coal<\/p>\n<\/div>\n

    Coal<\/b> (from the Old English term col<\/i>, which has meant “mineral of fossilized carbon” since the thirteent\u00a0century)is a combustible black or brownish-black sedimentary rock usually occurring in rock strata in layers or veins called coal beds<\/b> or coal seams<\/b>. The harder forms, such as anthracite coal, can be regarded as metamorphic rock because of later exposure to elevated temperature and pressure. Coal is composed primarily of carbon along with variable quantities of other elements, chiefly hydrogen, sulfur, oxygen, and nitrogen.<\/p>\n

    Throughout history, coal has been used as an energy resource, primarily burned for the production of electricity and\/or heat, and is also used for industrial purposes, such as refining metals. A fossil fuel, coal forms when dead plant matter is converted into peat, which in turn is converted into\u00a0lignite, then sub-bituminous coal, after that bituminous coal, and lastly anthracite. This involves biological and geological processes that take place over a long period. The United States Energy Information Administration estimates coal reserves at 948\u00d7109<\/sup><\/span> short tons (860 Gt).\u00a0One estimate for\u00a0resources is 18 000 Gt.<\/p>\n

    Coal is the largest source of energy for the generation of electricity worldwide, as well as one of the largest worldwide anthropogenic sources ofcarbon dioxide releases. In 1999, world gross carbon dioxide emissions from coal usage were 8,666 million tonnes of carbon dioxide.\u00a0In 2011, world gross emissions from coal usage were 14,416 million tonnes.\u00a0Coal-fired electric power generation emits around 2,000 pounds of carbon dioxide for every megawatt-hour generated, which is almost double the approximately 1100 pounds of carbon dioxide released by a natural gas-fired electric plant per megawatt-hour generated. Because of this higher carbon efficiency of natural gas generation, as the market in the United States has changed to reduce coal and increase natural gas generation, carbon dioxide emissions have fallen. Those measured in the first quarter of 2012 were the lowest of any recorded for the first quarter of any year since 1992\u00a0In 2013, the head of the UN climate agency advised that most of the world’s coal reserves should be left in the ground to avoid catastrophic global warming.<\/p>\n

    Coal is extracted from the ground by coal mining, either underground by shaft mining, or at ground level by open pit mining extraction. Since 1983 the world top coal producer has been China.\u00a0In 2011 China produced 3,520 million tonnes of coal \u2013 49.5% of 7,695 million tonnes world coal production. In 2011 other large producers were United States (993 million tonnes), India (589), European Union (576) and Australia (416).\u00a0In 2010 the largest exporters were Australia with 328 million tonnes (27.1% of world coal export) and Indonesia with 316 million tonnes (26.1%),\u00a0while the largest importers were Japan with 207 million tonnes (17.5% of world coal import), China with 195 million tonnes (16.6%) and South Korea with 126 million tonnes (10.7%).<\/p>\n

    Formation<\/span><\/h2>\n
    \"A<\/p>\n

    Figure 2. Coastal exposure of the Point Aconi Seam (Nova Scotia)<\/p>\n<\/div>\n

    At various times in the geologic past, the Earth had dense forests in low-lying wetland areas. Due to natural processes such as flooding, these forests were buried underneath soil. As more and more soil deposited over them, they were compressed. The temperature also rose as they sank deeper and deeper. As the process continued the plant matter was protected from biodegradation and oxidation, usually by mud or acidic water. This trapped the carbon in immense peat bogs that were eventually covered and deeply buried by sediments. Under high pressure and high temperature, dead vegetation was slowly converted to coal. As coal contains mainly carbon, the conversion of dead vegetation into coal is called carbonization.<\/p>\n

    The wide, shallow seas of the Carboniferous Period provided ideal conditions for coal formation, although coal is known from most geological periods. The exception is the coal gap in the Permian\u2013Triassic extinction event, where coal is rare. Coal is known from Precambrian strata, which predate land plants\u2014this coal is presumed to have originated from residues of algae.<\/p>\n

    Ranks<\/span><\/h2>\n

    As geological processes apply pressure to dead biotic material over time, under suitable conditions, its metamorphic grade increases successively into:<\/p>\n

      \n
    • Peat<\/strong>, considered to be a precursor of coal, has industrial importance as a fuel in some regions, for example, Ireland and Finland. In its dehydrated form, peat is a highly effective absorbent for fuel and oil spills on land and water. It is also used as a conditioner for soil to make it more able to retain and slowly release water.<\/li>\n
    • Lignite<\/strong>, or brown coal, is the lowest rank of coal and used almost exclusively as fuel for electric power generation. Jet, a compact form of lignite, is sometimes polished and has been used as an ornamental stone since the Upper Palaeolithic.<\/li>\n
    • Sub-bituminous coal<\/strong>, whose properties range from those of lignite to those of bituminous coal, is used primarily as fuel for steam-electric power generation and is an important source of light aromatic hydrocarbons for the chemical synthesis industry.<\/li>\n
    • Bituminous coal<\/strong> is a dense sedimentary rock, usually black, but sometimes dark brown, often with well-defined bands of bright and dull material; it is used primarily as fuel in steam-electric power generation, with substantial quantities used for heat and power applications in manufacturing and to make\u00a0coke.<\/li>\n
    • Steam coal<\/strong>” is a grade between bituminous coal and anthracite, once widely used as a fuel for steam locomotives. In this specialized use, it is sometimes known as “sea-coal” in the United States.\u00a0Small steam coal (dry small steam nuts or DSSN) was used as a fuel for domestic water heating.<\/li>\n
    • Anthracite<\/strong>, the highest rank of coal, is a harder, glossy black coal used primarily for residential and commercial space heating. It may be divided further into metamorphically altered bituminous coal and “petrified oil,” as from the deposits in Pennsylvania.<\/li>\n
    • Graphite<\/strong>, technically the highest rank, is difficult to ignite and is not commonly used as fuel\u2014it is mostly used in pencils and, when powdered, as a\u00a0lubricant.<\/li>\n<\/ul>\n

      The classification of coal is generally based on the content of volatiles. However, the exact classification varies between countries. According to the German classification, coal is classified as follows:<\/p>\n\n\n\n\n\n\n\n\n\n\n\n\n
      German Classification<\/th>\nEnglish Designation<\/th>\nVolatiles\u00a0%<\/th>\nC Carbon\u00a0%<\/th>\nH Hydrogen\u00a0%<\/th>\nO Oxygen\u00a0%<\/th>\nS Sulfur\u00a0%<\/th>\nHeat content kJ\/kg<\/th>\n<\/tr>\n
      Braunkohle<\/i><\/td>\nLignite (brown coal)<\/td>\n45\u201365<\/td>\n60\u201375<\/td>\n6.0\u20135.8<\/td>\n34-17<\/td>\n0.5-3<\/td>\n<28,470<\/td>\n<\/tr>\n
      Flammkohle<\/i><\/td>\nFlame coal<\/td>\n40-45<\/td>\n75-82<\/td>\n6.0-5.8<\/td>\n>9.8<\/td>\n~1<\/td>\n<32,870<\/td>\n<\/tr>\n
      Gasflammkohle<\/i><\/td>\nGas flame coal<\/td>\n35-40<\/td>\n82-85<\/td>\n5.8-5.6<\/td>\n9.8-7.3<\/td>\n~1<\/td>\n<33,910<\/td>\n<\/tr>\n
      Gaskohle<\/i><\/td>\nGas coal<\/td>\n28-35<\/td>\n85-87.5<\/td>\n5.6-5.0<\/td>\n7.3-4.5<\/td>\n~1<\/td>\n<34,960<\/td>\n<\/tr>\n
      Fettkohle<\/i><\/td>\nFat coal<\/td>\n19-28<\/td>\n87.5-89.5<\/td>\n5.0-4.5<\/td>\n4.5-3.2<\/td>\n~1<\/td>\n<35,380<\/td>\n<\/tr>\n
      Esskohle<\/i><\/td>\nForge coal<\/td>\n14-19<\/td>\n89.5-90.5<\/td>\n4.5-4.0<\/td>\n3.2-2.8<\/td>\n~1<\/td>\n<35,380<\/td>\n<\/tr>\n
      Magerkohle<\/i><\/td>\nNonbaking coal<\/td>\n10-14<\/td>\n90.5-91.5<\/td>\n4.0-3.75<\/td>\n2.8-3.5<\/td>\n~1<\/td>\n35,380<\/td>\n<\/tr>\n
      Anthrazit<\/i><\/td>\nAnthracite<\/td>\n7-12<\/td>\n>91.5<\/td>\n<3.75<\/td>\n<2.5<\/td>\n~1<\/td>\n<35,300<\/td>\n<\/tr>\n
      Note, the percentages are percent by mass of the indicated elements<\/th>\n<\/tr>\n<\/tbody>\n<\/table>\n

      The middle six grades in the table represent a progressive transition from the English-language sub-bituminous to bituminous coal, while the last class is an approximate equivalent to anthracite, but more inclusive (US anthracite has < 6% volatiles).<\/p>\n

      Cannel coal (sometimes called “candle coal”) is a variety of fine-grained, high-rank coal with significant hydrogen content. It consists primarily of “exinite” macerals, now termed “liptinite.”<\/p>\n

      Hilt’s law<\/span><\/h3>\n

      Hilt’s law is a geological term that states that, in a small area, the deeper the coal, the higher its rank (grade). The law holds true if the thermal gradient is entirely vertical, but metamorphism may cause lateral changes of rank, irrespective of depth.<\/p>\n

      Content<\/span><\/h2>\n\n\n\n\n\n\n
      Average content<\/caption>\n
      Substance<\/th>\nContent<\/th>\n<\/tr>\n
      Mercury (Hg)<\/td>\n0.10\u00b10.01\u00a0ppm<\/span><\/td>\n<\/tr>\n
      Arsenic (As)<\/td>\n1.4 \u2013 71 ppm<\/span><\/td>\n<\/tr>\n
      Selenium (Se)<\/td>\n3 ppm<\/span><\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

      Uses Today<\/span><\/h2>\n

      Coal as Fuel<\/span><\/h3>\n
      \"power<\/p>\n

      Figure 3. Castle Gate Power Plant near Helper, Utah, USA<\/p>\n<\/div>\n

      Coal is primarily used as a solid fuel to produce electricity and heat through combustion. World coal consumption was about 7.25 billion tonnes in 2010\u00a0<\/span>(7.99 billion short tons) and is expected to increase 48% to 9.05 billion tonnes (9.98 billion short tons) by 2030.<\/p>\n

      China produced 3.47 billion tonnes (3.83 billion short tons) in 2011. India produced about 578 million tonnes (637.1 million short tons) in 2011. 68.7% of China’s electricity comes from coal. The USA consumed about 13% of the world total in 2010, i.e. 951 million tonnes (1.05 billion short tons), using 93% of it for generation of electricity.\u00a046% of total power generated in the USA was done using coal.<\/p>\n

      \"Train<\/p>\n

      Figure 4. Coal rail cars<\/p>\n<\/div>\n

      When coal is used for electricity generation, it is usually pulverized and then combusted (burned) in a furnace with a boiler.\u00a0The furnace heat converts boiler water to steam, which is then used to spin turbines which turn generators and create electricity.\u00a0The thermodynamic efficiency of this process has been improved over time; some older coal-fired power stations have thermal efficiencies in the vicinity of 25%\u00a0whereas the newest supercritical and “ultra-supercritical” steam cycle turbines, operating at temperatures over 600\u00a0\u00b0C and pressures over 27 MPa (over 3900 psi), can practically achieve thermal efficiencies in excess of 45% (LHV basis) using anthracite fuel,\u00a0or around 43% (LHV basis) even when using lower-grade lignite fuel.\u00a0<\/span>Further thermal efficiency improvements are also achievable by improved pre-drying (especially relevant with high-moisture fuel such as lignite or biomass) and cooling technologies.<\/p>\n

      An alternative approach of using coal for electricity generation with improved efficiency is the integrated gasification combined cycle (IGCC) power plant. Instead of pulverizing the coal and burning it directly as fuel in the steam-generating boiler, the coal can be first gasified (see coal gasification) to create\u00a0syngas, which is burned in a gas turbine to produce electricity (just like natural gas is burned in a turbine). Hot exhaust gases from the turbine are used to raise steam in a heat recovery steam generator which powers a supplemental steam turbine. Thermal efficiencies of current IGCC power plants range from 39-42%\u00a0(HHV basis) or ~42-45% (LHV basis) for bituminous coal and assuming utilization of mainstream gasification technologies (Shell, GE Gasifier, CB&I). IGCC power plants outperform conventional pulverized coal-fueled plants in terms of pollutant emissions, and allow for relatively easy carbon capture.<\/p>\n

      At least 40% of the world’s electricity comes from coal,\u00a0and in 2012, about one-third of the United States’ electricity came from coal, down from approximately 49% in 2008.\u00a0As of 2012 in the United States, use of coal to generate electricity was declining, as plentiful supplies of natural gas obtained by hydraulic fracturing of tight shale formations became available at low prices.<\/p>\n

      In Denmark, a net electric efficiency of > 47% has been obtained at the coal-fired Nordjyllandsv\u00e6rket CHP Plant and an overall plant efficiency of up to 91% with cogeneration of electricity and district heating.\u00a0The multifuel-fired Aved\u00f8rev\u00e6rket CHP Plant just outside Copenhagen can achieve a net electric efficiency as high as 49%. The overall plant efficiency with cogeneration of electricity and district heating can reach as much as 94%.<\/p>\n

      An alternative form of coal combustion is as coal-water slurry fuel (CWS), which was developed in the Soviet Union. CWS significantly reduces emissions, improving the heating value of coal.\u00a0Other ways to use coal are combined heat and power cogeneration and an MHD topping cycle.<\/p>\n

      The total known deposits recoverable by current technologies, including highly polluting, low-energy content types of coal (i.e., lignite, bituminous), is sufficient for many years.\u00a0However, consumption is increasing and maximal production could be reached within decades (see world coal reserves, below). On the other hand much may have to be left in the ground to avoid climate change.<\/p>\n

      Gasification<\/span><\/h3>\n

      Coal gasification can be used to produce syngas, a mixture of carbon monoxide (CO) and hydrogen (H2<\/sub>) gas. Often syngas is used to fire gas turbines to produce electricity, but the versatility of syngas also allows it to be converted into transportation fuels, such as gasoline and diesel, through the Fischer-Tropsch process; alternatively, syngas can be converted into methanol, which can be blended into fuel directly or converted to gasoline via the methanol to gasoline process.[59]<\/sup> Gasification combined with Fischer-Tropsch technology is currently used by the Sasol chemical company of South Africa to make motor vehicle fuels from coal and natural gas. Alternatively, the hydrogen obtained from gasification can be used for various purposes, such as powering ahydrogen economy, making ammonia, or upgrading fossil fuels.<\/p>\n

      During gasification, the coal is mixed with oxygen and steam while also being heated and pressurized. During the reaction, oxygen and water molecules oxidize the coal into carbon monoxide (CO), while also releasing hydrogen gas (H2<\/sub>). This process has been conducted in both underground coal mines and in the production of town gas.<\/p>\n

      \n
      C (as Coal<\/i>) + O2<\/sub> + H2<\/sub>O \u2192 H2<\/sub> + CO<\/dd>\n<\/dl>\n

      If the refiner wants to produce gasoline, the syngas is collected at this state and routed into a Fischer-Tropsch reaction. If hydrogen is the desired end-product, however, the syngas is fed into thewater gas shift reaction, where more hydrogen is liberated.<\/p>\n

      \n
      CO + H2<\/sub>O \u2192 CO2<\/sub> + H2<\/sub><\/dd>\n<\/dl>\n

      In the past, coal was converted to make coal gas (town gas), which was piped to customers to burn for illumination, heating, and cooking.<\/p>\n

      Liquefaction<\/span><\/h3>\n

      Coal can also be converted into synthetic fuels equivalent to gasoline or diesel by several different direct processes (which do not intrinsically require gasification or indirect conversion).\u00a0In the direct liquefaction processes, the coal is either hydrogenated or carbonized. Hydrogenation processes are the Bergius process,\u00a0the SRC-I and SRC-II (Solvent Refined Coal) processes, the NUS Corporation hydrogenation process\u00a0and several other single-stage and two-stage processes.\u00a0In the process of low-temperature carbonization, coal is coked at temperatures between 360 and 750\u00a0\u00b0C (680 and 1,380\u00a0\u00b0F). These temperatures optimize the production of coal tars richer in lighter hydrocarbons than normal coal tar. The coal tar is then further processed into fuels. An overview of coal liquefaction and its future potential is available.<\/p>\n

      Coal liquefaction methods involve carbon dioxide (CO2<\/sub>) emissions in the conversion process. If coal liquefaction is done without employing either carbon capture and storage (CCS) technologies or biomass blending, the result is lifecycle greenhouse gas footprints that are generally greater than those released in the extraction and refinement of liquid fuel production from crude oil. If CCS technologies are employed, reductions of 5\u201312% can be achieved in Coal to Liquid (CTL) plants and up to a 75% reduction is achievable when co-gasifying coal with commercially demonstrated levels of biomass (30% biomass by weight) in coal\/biomass-to-liquids plants.\u00a0For future synthetic fuel projects, carbon dioxide sequestration is proposed to avoid releasing CO2<\/sub> into the atmosphere. Sequestration adds to the cost of production.<\/p>\n

      Refined Coal<\/span><\/h3>\n

      Refined coal is the product of a coal-upgrading technology that removes moisture and certain pollutants from lower-rank coals such as sub-bituminous and lignite (brown) coals. It is one form of several precombustion treatments and processes for coal that alter coal’s characteristics before it is burned. The goals of precombustion coal technologies are to increase efficiency and reduce emissions when the coal is burned. Depending on the situation, precombustion technology can be used in place of or as a supplement to postcombustion technologies to control emissions from coal-fueled boilers.<\/p>\n

      Industrial Processes\u00a0<\/span><\/h3>\n

      Finely ground bituminous coal, known in this application as sea coal, is a constituent of foundry sand. While the molten metal is in the mould, the coal burns slowly, releasing reducing gases at pressure, and so preventing the metal from penetrating the pores of the sand. It is also contained in “mould wash,” a paste or liquid with the same function applied to the mould before casting.\u00a0<\/span>Sea coal can be mixed with the clay lining (the “bod”) used for the bottom of a cupola furnace. When heated, the coal decomposes and the bod becomes slightly friable, easing the process of breaking open holes for tapping the molten metal.<\/p>\n

      Production of Chemicals<\/span><\/h3>\n

      Coal is an important feedstock in production of a wide range of chemical fertilizers and other chemical products. The main route to these products is coal gasification to produce syngas. Primary chemicals that are produced directly from the syngas include methanol, hydrogen and carbon monoxide, which are the chemical building blocks from which a whole spectrum of derivative chemicals are manufactured, including olefins, acetic acid, formaldehyde, ammonia,urea and others. The versatility of syngas as a precursor to primary chemicals and high-value derivative products provides the option of using relatively inexpensive coal to produce a wide range of valuable commodities.<\/p>\n

      Historically, production of chemicals from coal has been used since the 1950s and has become established in the market. According to the 2010 Worldwide Gasification Database,\u00a0a survey of current and planned gasifiers, from 2004 to 2007 chemical production increased its gasification product share from 37% to 45%. From 2008 to 2010, 22% of new gasifier additions were to be for chemical production.<\/p>\n

      Because the slate of chemical products that can be made via coal gasification can in general also use feedstocks derived from natural gas and petroleum, the chemical industry tends to use whatever feedstocks are most cost-effective. Therefore, interest in using coal tends to increase for higher oil and natural gas prices and during periods of high global economic growth that may strain oil and gas production. Also, production of chemicals from coal is of much higher interest in countries like South Africa, China, India and the United States where there are abundant coal resources. The abundance of coal combined with lack of natural gas resources in China is strong inducement for the coal to chemicals industry pursued there. In the United States, the best example of the industry is Eastman Chemical Company which has been successfully operating a coal-to-chemicals plant at its Kingsport, Tennessee, site since 1983. Similarly, Sasol has built and operated coal-to-chemicals facilities in South Africa.<\/p>\n

      Coal to chemical processes do require substantial quantities of water. As of 2013 much of the coal to chemical production was in the People’s Republic of China\u00a0where environmental regulation and water management\u00a0was weak.<\/p>\n

      World Coal Reserves<\/span><\/h3>\n

      The 948 billion short tons of recoverable coal reserves estimated by the Energy Information Administration are equal to about 4,196 BBOE (billion barrels of oil equivalent).\u00a0The amount of coal burned during 2007 was estimated at 7.075 billion short tons, or 133.179 quadrillion BTU’s.\u00a0This is an average of 18.8 million BTU per short ton. In terms of heat content, this is about 57,000,000 barrels (9,100,000\u00a0m3<\/sup>) of oil equivalent per day. By comparison in 2007, natural gas provided 51,000,000 barrels (8,100,000\u00a0m3<\/sup>) of oil equivalent per day, while oil provided 85,800,000 barrels (13,640,000\u00a0m3<\/sup>) per day.<\/p>\n

      \"Coal<\/p>\n

      Figure 5. A coal mine in Wyoming, United States. The United States has the world’s largest coal reserves.<\/p>\n<\/div>\n

      British Petroleum, in its 2007 report, estimated at 2006 end that there were 147 years reserves-to-production ratio based on proven<\/i> coal reserves worldwide. This figure only includes reserves classified as “proven”; exploration drilling programs by mining companies, particularly in under-explored areas, are continually providing new reserves. In many cases, companies are aware of coal deposits that have not been sufficiently drilled to qualify as “proven.” However, some nations haven’t updated their information and assume reserves remain at the same levels even with withdrawals.<\/p>\n

      Of the three fossil fuels, coal has the most widely distributed reserves; coal is mined in over 100 countries, and on all continents except Antarctica. The largest reserves are found in the United States, Russia, China, Australia and India.<\/p>\n\n\t\t\t

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