Difference between revisions of "Methane" - New World Encyclopedia

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[[Category:Public]]
 
{| class="toccolours" border="1" style="float: right; clear: right; margin: 0 0 1em 1em; border-collapse: collapse;"
 
{| class="toccolours" border="1" style="float: right; clear: right; margin: 0 0 1em 1em; border-collapse: collapse;"
 
! {{chembox header}} | Methane
 
! {{chembox header}} | Methane
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| [[Molar mass]] || 16.04 g/mol
 
| [[Molar mass]] || 16.04 g/mol
 
|-
 
|-
| Appearance || colourless gas
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| Appearance || colorless gas
 
|-
 
|-
 
| [[CAS registry number|CAS number]] || [74-82-8]
 
| [[CAS registry number|CAS number]] || [74-82-8]
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| [[Density]] and [[Phase (matter)|phase]] || 0.717 kg/m<sup>3</sup>, gas
 
| [[Density]] and [[Phase (matter)|phase]] || 0.717 kg/m<sup>3</sup>, gas
 
|-
 
|-
| [[Soluble|Solubility]] in [[Water (molecule)|water]] || 3.5 mL g/100 ml (17°C)
+
| [[Solubility]] in [[Water (molecule)|water]] || 3.5 mL g/100 ml (17°C)
 
|-
 
|-
 
<!-- | Other solvents e.g. [[ethanol]], [[acetone]] —>
 
<!-- | Other solvents e.g. [[ethanol]], [[acetone]] —>
 
<!-- | solubility info on other solvents —>
 
<!-- | solubility info on other solvents —>
 
<!-- |- —>
 
<!-- |- —>
| [[Melting point]] || &minus;182.5°C (90.6 K)
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| [[Melting point]] || &minus;182.5 °C (90.6 K)
 
|-
 
|-
| [[Boiling point]] || &minus;161.6°C (111.55 K)
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| [[Boiling point]] || &minus;161.6 °C (111.55 K)
 
|-
 
|-
 
| [[Triple point]] || 90.7 K, 0.117 bar
 
| [[Triple point]] || 90.7 K, 0.117 bar
 
|-
 
|-
| [[Critical temperature]] || 190.5°K (&minus;82.6°C) at 4.6 MPa (45 atm)
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| [[Critical temperature]] || 190.5 °K (&minus;82.6 °C) at 4.6 MPa (45 atm)
 
|-
 
|-
 
! {{chembox header}} | Structure
 
! {{chembox header}} | Structure
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| [[List of S-phrases|S-phrases]] || {{S2}}, {{S9}}, {{S16}}, {{S33}}
 
| [[List of S-phrases|S-phrases]] || {{S2}}, {{S9}}, {{S16}}, {{S33}}
 
|-
 
|-
| [[Flash point]] || &minus;188°C
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| [[Flash point]] || &minus;188 °C
 
|-
 
|-
| [[Autoignition temperature]] || 537°C
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| [[Autoignition temperature]] || 537 °C
 
|-
 
|-
| Maximum burning <br> temperature: || 2148°C
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| Maximum burning <br> temperature: || 2,148 °C
 
|-
 
|-
| [[Explosive limit]]s || 5&ndash;15%
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| [[Explosive limit]]s || 5&ndash;15 percent
 
|-
 
|-
 
! {{chembox header}} | [[Methane (data page)|Supplementary data page]]
 
! {{chembox header}} | [[Methane (data page)|Supplementary data page]]
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| Related compounds  || [[Methanol]]<br/>[[Chloromethane]]
 
| Related compounds  || [[Methanol]]<br/>[[Chloromethane]]
 
|-
 
|-
| {{chembox header}} | <small>Except where noted otherwise, data are given for<br> materials in their [[standard state|standard state (at 25 °C, 100 kPa)]]<br/>[[wikipedia:Chemical infobox|Infobox disclaimer and references]]</small>
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| {{chembox header}} | <small>Except where noted otherwise, data are given for<br> materials in their [[standard state|standard state (at 25 °C, 100 kPa)]]</small>
 
|-
 
|-
 
|}
 
|}
  
The simplest [[hydrocarbon]], '''methane''', is a [[gas]] with the [[chemical formula]] CH<sub>4</sub>. In chemical terms, it is classified as an ''[[alkane]]''.
+
'''Methane''' is the simplest [[hydrocarbon]], with the [[chemical formula]] CH<sub>4</sub>. In chemical terms, it is classified as an ''[[alkane]]''. At ordinary temperatures and pressures, it is a [[gas]]. It is a minor constituent of the [[Earth's atmosphere]], but it is the main component of [[natural gas]] and biogas. Large quantities of methane have been found in sediments on the ocean floor, where it is trapped in cage-like ice crystals known as ''methane clathrates''. Methane is widely used as a fuel, but it is also a starting material for the synthesis of other compounds. In nature, it plays an important role as a "greenhouse gas"&mdash;a gas that helps trap the Earth's heat, preventing the heat from escaping into space.
 +
{{toc}}
 +
== Occurrence and production ==
  
Pure methane is [[odor|odorless]].
+
The Earth's [[Earth|mantle]] is the main reservoir of methane, and large quantities of this gas have been found in geological deposits known as ''natural gas fields''. It occurs in association with other hydrocarbons and sometimes also [[helium]] and [[nitrogen]]. In general, natural gas is present in sediments buried deeper and at higher temperatures than those that contain [[petroleum]]. Natural gas fields are currently the main source from which methane is extracted for human use.
  
Methane is the main component of [[natural gas]], which is widely used as a [[fuel]].
+
Methane can also be extracted from [[coal]] deposits. It is the main component of the firedamp of coal mines. It is also emitted by mud [[volcano]]es that are connected to deep geological faults.
  
Methane is a [[greenhouse gas]] with a [[global warming potential]] over 100 years of 23 [http://www.grida.no/climate/ipcc_tar/wg1/248.htm (IPCC Third Assessment Report)] i.e. when averaged over 100 years each kg of CH<sub>4</sub> warms the earth 23 times as much as the same mass of CO<sub>2</sub>.  
+
'''Biogas''', produced by wetlands and landfills, is another source of methane. Biogas is a mixture of methane, carbon dioxide, and small amounts of other gases. It is generated by the microbial [[fermentation]] of organic matter&mdash;including manure, wastewater sludge, municipal solid waste, or other biodegradable feedstock&mdash;under anaerobic conditions. Biogas is also called '''swamp gas''', '''landfill gas''', or '''marsh gas''', depending on where it is produced.
  
== Occurrence ==
+
[[Image:Burning hydrate inlay US Office Naval Research.jpg|left|frame|"Burning ice." Methane clathrate consists of methane trapped in ice crystals. Upon heating, this material releases methane, which can burn. Inset: Molecular structure of a methane clathrate.<br>Source: [[USGS]]]]
  
The Earth's [[Earth|mantle]] is the main reservoir of methane, and large quantities of this gas have been found in geological deposits known as ''natural gas fields''. It occurs in association with other hydrocarbons and sometimes also [[helium]] and [[nitrogen]]. In general, natural gas is present in sediments buried deeper and at higher temperatures than those that contain [[petroleum]]. It is formed by the decay of [[organic matter]] under anaerobic conditions (that is, in the absence of oxygen) beneath the Earth's surface. Natural gas fields are currently the main source from which methane is extracted for human use.
+
Large deposits of methane have been found in a form known as '''methane clathrate''', under sediments on the [[ocean]] floors. Also known as '''methane hydrate''' or '''methane ice''', it consists of methane molecules held in cage-like, crystalline structures of frozen water. Methane clathrates are thought to be formed when methane gas streams rising from geological faults come in contact with cold seawater. One liter of methane clathrate solid would contain, on average, 168 liters of methane gas (at 25 °C and 100 kPa pressure).
  
'''Biogas''' is another source of methane. It is a mixture of methane, carbon dioxide, and small amounts of other gases. It is generated by the [[fermentation]] of organic matter&mdash;including manure, wastewater sludge, municipal solid waste, or other biodegradable feedstock&mdash;under anaerobic conditions. Biogas is also called '''swamp gas''', '''landfill gas''', or '''marsh gas''', depending on where it is produced.
+
In addition to the above-mentioned sources, methane is produced by the digestive systems of ruminants, termites, rice paddies, and oceans [http://www.epa.gov/methane/sources.html#natural], [http://www.grida.no/climate/ipcc_tar/wg1/134.htm#4211].
  
[[Image:Burning hydrate inlay US Office Naval Research.jpg|left|frame|"Burning ice." Methane clathrate consists of methane trapped in ice crystals. Upon heating, this material releases methane, which can burn. Inset: Molecular structure of a methane clathrate.<br>Source: [[USGS]]]]
+
Until recently, the consensus view has been that most of the methane from biological sources was produced by processes in oxygen-poor environments. In January 2006, however, a group of researchers reported that plants exposed to atmospheric levels of oxygen also constitute an important source of methane [http://www.nature.com/nature/journal/v439/n7073/abs/nature04420.html], [http://news.bbc.co.uk/2/hi/science/nature/4604332.stm]. The researchers noted that "this newly identified source may have important implications for the global methane budget and may call for a reconsideration of the role of natural methane sources in past climate change."
  
Methane can also be extracted from [[coal]] deposits. In industrial settings, it is produced by chemical reactions between hydrogen and common atmospheric gases. In addition, methane is a component of cattle flatulence.
+
===Artificial synthesis===
  
Large deposits of methane have been found in a form known as '''methane clathrate''', under sediments on the [[ocean]] floors. Also known as '''methane hydrate''' or '''methane ice''', it consists of methane molecules held in cagelike, crystalline structures of frozen water. Methane clathrates are thought to be formed when methane gas streams rising from geological faults come in contact with cold seawater. One liter of methane clathrate solid would contain, on average, 168 liters of methane gas (at 25°C and 100 kPa pressure).
+
In the laboratory, methane can be produced by the direct reaction of [[carbon]] with [[hydrogen]], or aluminum carbide with [[water]]. In industrial settings, methane is produced by chemical reactions between hydrogen and common atmospheric gases.
  
 
==Properties==
 
==Properties==
  
At room temperature and pressure, methane is a colorless, odorless gas. It has a boiling point of −162°C at 1 [[Atmosphere (unit)|atmosphere]] pressure and is highly flammable. It is violently reactive with [[oxidizer]]s, [[halogen]]s, and some halogen compounds.
+
At room temperature and pressure, methane is a colorless, odorless gas, lighter than air. At a pressure of 1 atmosphere, its boiling point is -161.5 °C (-258.7 °F) and melting point is -182.5 °C (-296.5 °F). It is highly flammable and reacts violently with [[oxidizer]]s, [[halogen]]s, and some halogen compounds.
  
Each molecule of methane consists of four atoms of [[hydrogen]] attached to a single atom of [[carbon]] through [[covalent bond]]s. The molecule is shaped like a tetrahedron, with the carbon atom at the center and the four hydrogen atoms occupying the four corners of the tetrahedron.
+
Each molecule of methane is small, consisting of four atoms of [[hydrogen]] attached to a single atom of [[carbon]] through [[covalent bond]]s. The molecule is shaped like a tetrahedron, with the carbon atom at the center and the four hydrogen atoms occupying the four corners of the tetrahedron. Unlike water molecules, which are polar and attract one another, methane molecules are non-polar and do not have much attraction for one another. This is the reason why, at room temperature, methane is a gas while water is a liquid.
  
 
=== Reactions of methane ===
 
=== Reactions of methane ===
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Here, X is either [[fluorine]] (F), [[chlorine]] (Cl), [[bromine]] (Br), or sometimes [[iodine]] (I).
 
Here, X is either [[fluorine]] (F), [[chlorine]] (Cl), [[bromine]] (Br), or sometimes [[iodine]] (I).
  
This reaction may continue, so that CH<sub>3</sub>X reacts with X<sub>2</sub> to produce CH<sub>2</sub>X<sub>2</sub>; CH<sub>2</sub>X<sub>2</sub> in turn can react with X<sub>2</sub> to produce CHX<sub>3</sub>; and CHX<sub>3</sub> can react further with X<sub>2</sub> to produce CX<sub>4</sub>.
+
This reaction may continue, so that CH<sub>3</sub>X reacts with X<sub>2</sub> to produce CH<sub>2</sub>X<sub>2</sub>; CH<sub>2</sub>X<sub>2</sub> in turn can react with X<sub>2</sub> to produce CHX<sub>3</sub>; and CHX<sub>3</sub> can react further with X<sub>2</sub> to produce CX<sub>4</sub>.
  
 
== Potential health effects ==
 
== Potential health effects ==
  
Methane is not [[toxic]], but because it is highly flammable, it can form mixtures with air that are [[explosive]]. In addition, if it displaces oxygen within an enclosed space, and the oxygen concentration drops below 18%, it can lead to asphyxiation. For these reasons, commercially available methane is usually mixed with small quantities of ''odorants''&mdash;strong-smelling [[sulfur]] compounds, such as [[ethanethiol|ethyl mercaptan]]*, to enable the detection of leaks.
+
Methane is not [[toxic]], but because it is highly flammable it can form mixtures with air that are [[explosive]]. In addition, if it displaces oxygen within an enclosed space, and the oxygen concentration drops below 18 percent, it can lead to asphyxiation. For these reasons, commercially available methane is usually mixed with small quantities of ''odorants''&mdash;strong-smelling [[sulfur]] compounds, such as [[ethanethiol|ethyl mercaptan]], to enable the detection of leaks.
  
 
When structures are built on or near [[landfill]]s, methane off-gas can penetrate the building interior and expose occupants to significant levels of methane. Some buildings have specially engineered recovery systems below their basements, to actively capture such fugitive off-gas and vent it away from the building.
 
When structures are built on or near [[landfill]]s, methane off-gas can penetrate the building interior and expose occupants to significant levels of methane. Some buildings have specially engineered recovery systems below their basements, to actively capture such fugitive off-gas and vent it away from the building.
 
== Uses ==
 
=== Fuel ===
 
 
:''For more on the use of methane as a fuel, see: [[Natural gas]].''
 
 
Methane is an important fuel. Being the simplest hydrocarbon, the combustion of methane produces more heat per gram than other hydrocarbons. In addition, compared to other hydrocarbon fuels, burning methane produces less [[carbon dioxide]] for each unit of heat released.
 
 
In the form of natural gas, methane is regularly distributed via gas pipelines. In many cities, it is piped into homes for domestic [[heating]] and cooking purposes. Moreover, large quantities are burned to drive gas or steam turbines, to generate [[electricity]].
 
 
When biogas is used as a fuel, it provides a convenient way to turn waste into electricity. The process of producing biogas decreases the amount of waste to be disposed of and destroys disease-causing [[microbe]]s that are present in the waste stream.
 
 
=== Industrial uses ===
 
 
In the chemical industry, methane is the feedstock of choice for the production of [[hydrogen]], [[methanol]]*, [[acetic acid]]*, and [[acetic anhydride]]*. To produce any of these chemicals, methane is first made to react with steam in the presence of a [[nickel]] catalyst at high temperatures (700&ndash;1,100°C). The chemical equation is as follows:
 
 
: CH<sub>4</sub> + H<sub>2</sub>O → CO + 3H<sub>2</sub>
 
 
The product, known as "synthesis gas," is a mixture of [[carbon monoxide]]* and hydrogen. Synthesis gas is then manipulated to produce the intended products.
 
 
Moreover, [[acetylene]] is prepared by passing methane through an [[electric arc]]*. When methane is made to react with [[chlorine]] gas, various chloromethanes are produced: chloromethane, dichloromethane, [[chloroform]]*, and [[carbon tetrachloride]]*. The use of these chemicals, however, is declining. Acetylene may be replaced by less costly substitutes, and the chloromethanes are used less often because of health and environmental concerns.
 
  
 
== Methane in the Earth's atmosphere ==
 
== Methane in the Earth's atmosphere ==
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[[Image:Ch4rug multicolor.jpg|thumb|250px|Methane concentrations graph]]
 
[[Image:Ch4rug multicolor.jpg|thumb|250px|Methane concentrations graph]]
  
Scientists think that early in the Earth's history&mdash;about 3.5 billion years ago&mdash;there was 1,000 times as much methane in the atmosphere as there is now. The earliest methane was released into the atmosphere by volcanic activity. In addition, ancient bacteria contributed to the methane concentration by converting hydrogen and carbon dioxide into methane and water. Oxygen did not become a major part of the atmosphere until photosynthetic organisms emerged later in Earth's history. In the absence of oxygen, methane stayed in the atmosphere longer and at higher concentrations than it does today.
+
Scientists think that early in the Earth's history&mdash;about 3.5 billion years ago&mdash;there was one thousand times as much methane in the atmosphere as there is now. The earliest methane was released into the atmosphere by volcanic activity. In addition, ancient bacteria contributed to the methane concentration by converting hydrogen and carbon dioxide into methane and water. Oxygen did not become a major part of the atmosphere until photosynthetic organisms emerged later in Earth's history. In the absence of oxygen, methane stayed in the atmosphere longer and at higher concentrations than it does today.
  
===Recent emissions===
+
===Recent status===
[[Image:AtmosphericMethane.png|thumb|250px|Computer models showing the amount of methane (parts per million by volume) at the surface (top) and in the stratosphere (bottom).]]
+
[[Image:AtmosphericMethane.png|thumb|250px|Computer models showing the amount of methane (parts per million by volume) at the surface (top) and in the stratosphere (bottom)]]
  
On the Earth's surface, methane is produced by various natural and human-influenced sources. This methane is carried into the stratosphere by rising air, especially at the tropics. Currently, methane is a minor constituent of our planet's [[Earth's atmosphere|atmosphere]].
+
Currently, methane is a minor constituent of our planet's [[Earth's atmosphere|atmosphere]]. The average concentration of methane at the Earth's surface in 1998 has been estimated as 1,745 ppb (parts per billion) [http://www.grida.no/climate/ipcc_tar/wg1/134.htm#4211]. Its concentration is higher in the northern hemisphere, as most sources (natural and human) are greater there. In addition, the concentration varies seasonally, with a minimum in the late summer.
  
Surface-level sources of methane include wetlands, digestive processes of ruminants, natural gas systems, landfills, coal mining, oceans, termites, methane hydrates, manure management, and wastewater treatment facilities [http://www.epa.gov/methane/sources.html#natural], [http://www.grida.no/climate/ipcc_tar/wg1/134.htm#4211]. Methane is also emitted by mud [[volcano]]es that are connected to deep geological faults.
+
=== Removal processes ===
  
Until recently, the consensus view has been that most of the methane from biological sources was produced by processes in oxygen-poor environments. In January 2006, however, a group of researchers reported that plants exposed to atmospheric levels of oxygen are also an important source of methane [http://www.nature.com/nature/journal/v439/n7073/abs/nature04420.html], [http://news.bbc.co.uk/2/hi/science/nature/4604332.stm]. The researchers noted that "this newly identified source may have important implications for the global methane budget and may call for a reconsideration of the role of natural methane sources in past climate change."
+
The main process by which methane is removed from the Earth's atmosphere is its reaction with the [[hydroxyl radical]] ('''·'''OH)&mdash;a reactive entity that may be produced when a [[cosmic ray]] strikes a molecule of water vapor. The chemical change can be written as follows.
  
The average concentration of methane at the Earth's surface in 1998 has been estimated as 1,745 ppb (parts per billion) [http://www.grida.no/climate/ipcc_tar/wg1/134.htm#4211]. Its concentration is higher in the northern hemisphere, as most sources (natural and human) are greater there. In addition, the concentration varies seasonally, with a minimum in the late summer.
+
: CH<sub>4</sub> + '''·'''OH → '''·'''CH<sub>3</sub> + H<sub>2</sub>O
  
=== Removal processes ===
+
Two additional sets of processes that remove minor quantities of methane are: (a) the activity of aerobic microbes in soils, and (b) reactions with '''·'''OH, '''·'''Cl, and '''·'''O(<sup>1</sup>D) in the stratosphere. Based on these processes, the estimated lifetime of methane in the atmosphere has been calculated to be 8.4 years [http://www.grida.no/climate/ipcc_tar/wg1/134.htm#4211].
  
The main process by which methane is removed from the Earth's atmosphere is its reaction with the [[hydroxyl radical]]* ('''·'''OH)&mdash;a reactive entity that may be produced when a [[cosmic ray]] strikes a molecule of water vapor. The chemical change can be written as follows.
+
== Uses ==
 +
=== Fuel ===
  
: CH<sub>4</sub> + '''·'''OH → '''·'''CH<sub>3</sub> + H<sub>2</sub>O
+
:''For more on the use of methane as a fuel, see: [[Natural gas]].''
  
Two additional sets of processes that remove minor quantities of methane are: (a) the activity of aerobic microbes in soils, and (b) reactions with '''·'''OH, '''·'''Cl, and '''·'''O(<sup>1</sup>D) in the stratosphere. Based on these processes, the estimated lifetime of methane in the atmosphere has been calculated to be 8.4 years [http://www.grida.no/climate/ipcc_tar/wg1/134.htm#4211].
+
Methane is an important fuel. Being the simplest hydrocarbon, the combustion of methane produces more heat per gram than other hydrocarbons. In addition, compared to other hydrocarbon fuels, burning methane produces less [[carbon dioxide]] for each unit of heat released.
  
== Greenhouse gas ==
+
In the form of natural gas, methane is regularly distributed via gas pipelines. In many cities, it is piped into homes for domestic [[heating]] and cooking purposes. Moreover, large quantities are burned to drive gas or steam turbines, to generate [[electricity]].
  
Methane in the Earth's atmosphere is an important greenhouse gas. The Earth absorbs some of the Sun's energy and then emits energy at longer wavelengths. Greenhouse gases (including water vapor, carbon dioxide, and methane) absorb the heat being emitted and prevent it from escaping into space. In this manner, greenhouse gases play a vital role in keeping the planet warm enough for human habitation.
+
When biogas is used as a fuel, it provides a convenient way to turn waste into electricity. The process of producing biogas decreases the amount of waste to be disposed of and destroys disease-causing [[microbe]]s that are present in the waste stream.
  
888888888
+
=== Industrial uses ===
There is also concern about global warming, based on a "greenhouse effect" caused by increasing emissions of carbon dioxide and particulate matter, and this subject is the focus of intense study and debate.
 
  
8888888888
+
In the chemical industry, methane is the feedstock of choice for the production of [[hydrogen]], [[methanol]], [[acetic acid]], and [[acetic anhydride]]. To produce any of these chemicals, methane is first made to react with steam in the presence of a [[nickel]] catalyst at high temperatures (700&ndash;1,100 °C). The chemical equation is as follows:
  
[[Human]] activity raises levels of greenhouse gases primarily by releasing carbon dioxide, but other gases, e.g. methane, are not negligible.<ref>{{cite web| url=http://www.grida.no/climate/ipcc_tar/wg1/fig6-6.htm|title=Climate Change 2001: Working Group I: The Scientific Basis: figure 6-6| accessdate=2006-05-01}}</ref>
+
: CH<sub>4</sub> + H<sub>2</sub>O → CO + 3H<sub>2</sub>
  
The concentrations of several greenhouse gases have increased over time<ref>{{cite web| url=http://www.grida.no/climate/ipcc_tar/wg1/016.htm| title=Climate Change 2001: Working Group I: The Scientific Basis: C.1 Observed Changes in Globally Well-Mixed Greenhouse Gas Concentrations and Radiative Forcing| accessdate=2006-05-01}}</ref> due to human activities, such as:
+
The product, known as "synthesis gas," is a mixture of [[carbon monoxide]] and hydrogen. Synthesis gas is then manipulated to produce the intended products.
* burning of [[fossil fuel]]s and [[deforestation]] leading to higher carbon dioxide concentrations,
 
* [[livestock]] and paddy [[rice]] farming, land use and wetland changes, pipeline losses, and covered vented landfill emissions leading to higher methane atmospheric concentrations, many of the newer style fully vented septic systems that enhance and target the fermentation process also are major sources of atmospheric methane.
 
* the use of CFCs in [[refrigeration]] systems. The use of CFCs and [[halon]]s in [[fire extinguisher|fire suppression]] systems and various manufacturing processes.
 
  
According to the global warming hypothesis, greenhouse gases from industry and agriculture have played a major role in the recently observed [[global warming]].
+
Moreover, [[acetylene]] is prepared by passing methane through an [[electric arc]]. When methane is made to react with [[chlorine]] gas, various chloromethanes are produced: chloromethane, dichloromethane, [[chloroform]], and [[carbon tetrachloride]]. The use of these chemicals, however, is declining. Acetylene may be replaced by less costly substitutes, and the chloromethanes are used less often because of health and environmental concerns.
88888888888
 
  
with a global warming potential of 23 over a 100-year period. In other words, when averaged over 100 years, each kilogram of methane warms the Earth 23 times as much as the same mass of carbon dioxide.
+
== Greenhouse gas ==
  
Its concentation has increased by about 150% since 1750 and it accounts for 20% of the total [[radiative forcing]] from all of the long-lived and globally mixed greenhouse gases [http://www.grida.no/climate/ipcc_tar/wg1/017.htm].
+
Methane in the Earth's atmosphere is an important "greenhouse gas" that contributes to the "greenhouse effect." The Earth absorbs some of the Sun's energy and then emits energy at longer wavelengths. Greenhouse gases (including water vapor, carbon dioxide, and methane) absorb the heat being emitted and prevent it from escaping into space. In this manner, greenhouse gases play a vital role in keeping the planet warm enough for human habitation.
  
 +
The current concern about global warming is based on reports that the concentrations of greenhouse gases have risen in recent years, mainly as a result of human activities, leading to an upward trend in the Earth's temperature [http://www.grida.no/climate/ipcc_tar/wg1/016.htm]. Some have contended that if this warming trend is not reversed, it could soon lead to dire consequences. This subject, however, is the focus of intense study and debate.
  
*"Although the major contributors to the global CH4 budget likely have been identified, most of them are quite uncertain quantitatively because of the difficulty in assessing emission rates of highly variable biospheric sources. The limitations of poorly quantified and characterised CH4 source strengths inhibit the prediction of future CH4 atmospheric concentrations (and hence its contribution to radiative forcing) for any given anthropogenic emission scenario, particularly since both natural emissions and the removal of CH4 can be influenced substantially by climate change." [http://www.grida.no/climate/ipcc_tar/wg1/017.htm]
+
In the case of methane, its concentration has reportedly increased by about 150 percent since 1750. In addition, its "global warming potential" is estimated to be 23 over a 100-year period. In other words, when averaged over one hundred years, each kilogram of methane warms the Earth 23 times as much as the same mass of carbon dioxide. Nonetheless, the rates of emission of methane by different sources in the [[biosphere]] are highly variable and difficult to assess. Consequently, it is difficult to predict future concentrations of methane in the atmosphere [http://www.grida.no/climate/ipcc_tar/wg1/017.htm].
  
 
==Extraterrestrial methane==
 
==Extraterrestrial methane==
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* [[Mars]]
 
* [[Mars]]
 
* [[Saturn (planet)|Saturn]]
 
* [[Saturn (planet)|Saturn]]
** [[Iapetus (moon)|Iapetus]]*
+
** [[Iapetus (moon)|Iapetus]]
** [[Titan (moon)|Titan]]*
+
** [[Titan (moon)|Titan]]
** [[Enceladus (moon)|Enceladus]]*
+
** [[Enceladus (moon)|Enceladus]]
 
* [[Neptune (planet)|Neptune]]
 
* [[Neptune (planet)|Neptune]]
** [[Triton (moon)|Triton]]*
+
** [[Triton (moon)|Triton]]
 
* [[Uranus (planet)|Uranus]]
 
* [[Uranus (planet)|Uranus]]
** [[Ariel (moon)|Ariel]]*
+
** [[Ariel (moon)|Ariel]]
** [[Miranda (moon)|Miranda]]*
+
** [[Miranda (moon)|Miranda]]
** [[Oberon (moon)|Oberon]]*
+
** [[Oberon (moon)|Oberon]]
** [[Titania (moon)|Titania]]*
+
** [[Titania (moon)|Titania]]
** [[Umbriel (moon)|Umbriel]]*
+
** [[Umbriel (moon)|Umbriel]]
* [[Comet Halley]]*
+
* [[Comet Halley]]
* [[Comet Hyakutake]]*
+
* [[Comet Hyakutake]]
* [[2003 UB313]]*
+
* [[2003 UB313]]
  
 
Traces of methane gas are present in the thin atmosphere of the Earth's [[Moon]]. Methane has also been detected in interstellar clouds.
 
Traces of methane gas are present in the thin atmosphere of the Earth's [[Moon]]. Methane has also been detected in interstellar clouds.
  
 
==See also==  
 
==See also==  
*[[Alkane]], a type of [[hydrocarbon]] of which methane is simplest member.
 
*[[Methanogen]], [[archaea]] that produce methane as a metabolic by-product.
 
*[[Methanotroph]],  [[bacteria]] that are able to grow using methane as their only source of carbon and energy.
 
  
==External links==
+
* [[Alkane]]
*[http://www.gasresources.net Methane thermodynamics]
+
* [[Butane]]
*[http://www-cms.llnl.gov/s-t/cheetah_methane_str.html Inorganic Methane]
+
* [[Ethane]]
*[http://www.ilo.org/public/english/protection/safework/cis/products/icsc/dtasht/_icsc02/icsc0291.htm International Chemical Safety Card 0291]
+
* [[Hydrocarbon]]
*[http://marine.usgs.gov/fact-sheets/gas-hydrates/title.html Methane Hydrates]
+
* [[Methanogen]]
*[http://box27.bluehost.com/~edsanvil/wiki/index.php?title=Methane Computational Chemistry Wiki]
+
* [[Natural gas]]
*[http://www.bluerhinos.co.uk/molview/indv.php?id=7 Molview from bluerhinos.co.uk] See Methane in 3D
+
* [[Propane]]
 +
 
 +
== References ==
 +
 
 +
* McMurry, John. 2004. ''Organic Chemistry,'' 6th ed. Belmont, CA: Brooks/Cole. ISBN 0534420052.
 +
 
 +
* Morrison, Robert T., and Robert N. Boyd. 1992. ''Organic Chemistry,'' 6th ed. Englewood Cliffs, NJ: Prentice Hall. ISBN 0136436692.
 +
 
 +
* Solomons, T.W. Graham, and Craig B. Fryhle. 2004. ''Organic Chemistry,'' 8th ed. Hoboken, NJ: John Wiley. ISBN 0471417998.
 +
 
  
*{{ecb}}
 
  
 
{{alkanes}}
 
{{alkanes}}
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[[Category:Physical sciences]]
 
[[Category:Physical sciences]]
 
[[Category:Chemistry]]
 
[[Category:Chemistry]]
[[Category:Alkanes]]
+
 
  
 
{{credit3|Methane|60320215|Biogas|59599541|Methane_clathrate|61473411}}
 
{{credit3|Methane|60320215|Biogas|59599541|Methane_clathrate|61473411}}

Latest revision as of 16:00, 21 October 2014


Methane
Methane Methane
General
Other names Marsh gas
Molecular formula CH4
SMILES C
Molar mass 16.04 g/mol
Appearance colorless gas
CAS number [74-82-8]
Properties
Density and phase 0.717 kg/m3, gas
Solubility in water 3.5 mL g/100 ml (17°C)
Melting point −182.5 °C (90.6 K)
Boiling point −161.6 °C (111.55 K)
Triple point 90.7 K, 0.117 bar
Critical temperature 190.5 °K (−82.6 °C) at 4.6 MPa (45 atm)
Structure
Molecular shape tetrahedral
Symmetry group Td
Dipole moment Zero
Hazards
MSDS External MSDS
EU classification Highly flammable (F+)
NFPA 704

NFPA 704.svg

4
1
0
 
R-phrases R12
S-phrases S2, S9, S16, S33
Flash point −188 °C
Autoignition temperature 537 °C
Maximum burning
temperature:
2,148 °C
Explosive limits 5–15 percent
Supplementary data page
Structure and
properties
Thermodynamic
data
Spectral data UV, IR, NMR, MS
Related compounds
Related alkanes Ethane
Propane
Related compounds Methanol
Chloromethane
Except where noted otherwise, data are given for
materials in their standard state (at 25 °C, 100 kPa)

Methane is the simplest hydrocarbon, with the chemical formula CH4. In chemical terms, it is classified as an alkane. At ordinary temperatures and pressures, it is a gas. It is a minor constituent of the Earth's atmosphere, but it is the main component of natural gas and biogas. Large quantities of methane have been found in sediments on the ocean floor, where it is trapped in cage-like ice crystals known as methane clathrates. Methane is widely used as a fuel, but it is also a starting material for the synthesis of other compounds. In nature, it plays an important role as a "greenhouse gas"—a gas that helps trap the Earth's heat, preventing the heat from escaping into space.

Occurrence and production

The Earth's mantle is the main reservoir of methane, and large quantities of this gas have been found in geological deposits known as natural gas fields. It occurs in association with other hydrocarbons and sometimes also helium and nitrogen. In general, natural gas is present in sediments buried deeper and at higher temperatures than those that contain petroleum. Natural gas fields are currently the main source from which methane is extracted for human use.

Methane can also be extracted from coal deposits. It is the main component of the firedamp of coal mines. It is also emitted by mud volcanoes that are connected to deep geological faults.

Biogas, produced by wetlands and landfills, is another source of methane. Biogas is a mixture of methane, carbon dioxide, and small amounts of other gases. It is generated by the microbial fermentation of organic matter—including manure, wastewater sludge, municipal solid waste, or other biodegradable feedstock—under anaerobic conditions. Biogas is also called swamp gas, landfill gas, or marsh gas, depending on where it is produced.

"Burning ice." Methane clathrate consists of methane trapped in ice crystals. Upon heating, this material releases methane, which can burn. Inset: Molecular structure of a methane clathrate.
Source: USGS

Large deposits of methane have been found in a form known as methane clathrate, under sediments on the ocean floors. Also known as methane hydrate or methane ice, it consists of methane molecules held in cage-like, crystalline structures of frozen water. Methane clathrates are thought to be formed when methane gas streams rising from geological faults come in contact with cold seawater. One liter of methane clathrate solid would contain, on average, 168 liters of methane gas (at 25 °C and 100 kPa pressure).

In addition to the above-mentioned sources, methane is produced by the digestive systems of ruminants, termites, rice paddies, and oceans [1], [2].

Until recently, the consensus view has been that most of the methane from biological sources was produced by processes in oxygen-poor environments. In January 2006, however, a group of researchers reported that plants exposed to atmospheric levels of oxygen also constitute an important source of methane [3], [4]. The researchers noted that "this newly identified source may have important implications for the global methane budget and may call for a reconsideration of the role of natural methane sources in past climate change."

Artificial synthesis

In the laboratory, methane can be produced by the direct reaction of carbon with hydrogen, or aluminum carbide with water. In industrial settings, methane is produced by chemical reactions between hydrogen and common atmospheric gases.

Properties

At room temperature and pressure, methane is a colorless, odorless gas, lighter than air. At a pressure of 1 atmosphere, its boiling point is -161.5 °C (-258.7 °F) and melting point is -182.5 °C (-296.5 °F). It is highly flammable and reacts violently with oxidizers, halogens, and some halogen compounds.

Each molecule of methane is small, consisting of four atoms of hydrogen attached to a single atom of carbon through covalent bonds. The molecule is shaped like a tetrahedron, with the carbon atom at the center and the four hydrogen atoms occupying the four corners of the tetrahedron. Unlike water molecules, which are polar and attract one another, methane molecules are non-polar and do not have much attraction for one another. This is the reason why, at room temperature, methane is a gas while water is a liquid.

Reactions of methane

Combustion

When methane is burned in the presence of oxygen, the reaction—called a combustion reaction—produces carbon dioxide, water, and a large amount of heat. In molecular terms, the chemical reaction can be represented as follows:

CH4 + 2O2 → CO2 + 2H2O + heat

Hydrogen activation

In methane, the carbon-hydrogen covalent bond is among the strongest in all hydrocarbons. In chemical terms, there is a high "activation barrier" to break this C-H bond—in other words, considerable energy is required to break it. Nonetheless, methane is still the principal starting material for the manufacture of hydrogen. The search for catalysts that can lower the activation barrier and other small-molecule alkanes is an area of research with considerable industrial significance.

Reactions with halogens

Under the proper conditions, methane reacts with all the halogens. The general reaction can be represented as follows:

CH4 + X2 → CH3X + HX

Here, X is either fluorine (F), chlorine (Cl), bromine (Br), or sometimes iodine (I).

This reaction may continue, so that CH3X reacts with X2 to produce CH2X2; CH2X2 in turn can react with X2 to produce CHX3; and CHX3 can react further with X2 to produce CX4.

Potential health effects

Methane is not toxic, but because it is highly flammable it can form mixtures with air that are explosive. In addition, if it displaces oxygen within an enclosed space, and the oxygen concentration drops below 18 percent, it can lead to asphyxiation. For these reasons, commercially available methane is usually mixed with small quantities of odorants—strong-smelling sulfur compounds, such as ethyl mercaptan, to enable the detection of leaks.

When structures are built on or near landfills, methane off-gas can penetrate the building interior and expose occupants to significant levels of methane. Some buildings have specially engineered recovery systems below their basements, to actively capture such fugitive off-gas and vent it away from the building.

Methane in the Earth's atmosphere

Early Earth's atmosphere

Methane concentrations graph

Scientists think that early in the Earth's history—about 3.5 billion years ago—there was one thousand times as much methane in the atmosphere as there is now. The earliest methane was released into the atmosphere by volcanic activity. In addition, ancient bacteria contributed to the methane concentration by converting hydrogen and carbon dioxide into methane and water. Oxygen did not become a major part of the atmosphere until photosynthetic organisms emerged later in Earth's history. In the absence of oxygen, methane stayed in the atmosphere longer and at higher concentrations than it does today.

Recent status

Computer models showing the amount of methane (parts per million by volume) at the surface (top) and in the stratosphere (bottom)

Currently, methane is a minor constituent of our planet's atmosphere. The average concentration of methane at the Earth's surface in 1998 has been estimated as 1,745 ppb (parts per billion) [5]. Its concentration is higher in the northern hemisphere, as most sources (natural and human) are greater there. In addition, the concentration varies seasonally, with a minimum in the late summer.

Removal processes

The main process by which methane is removed from the Earth's atmosphere is its reaction with the hydroxyl radical (·OH)—a reactive entity that may be produced when a cosmic ray strikes a molecule of water vapor. The chemical change can be written as follows.

CH4 + ·OH → ·CH3 + H2O

Two additional sets of processes that remove minor quantities of methane are: (a) the activity of aerobic microbes in soils, and (b) reactions with ·OH, ·Cl, and ·O(1D) in the stratosphere. Based on these processes, the estimated lifetime of methane in the atmosphere has been calculated to be 8.4 years [6].

Uses

Fuel

For more on the use of methane as a fuel, see: Natural gas.

Methane is an important fuel. Being the simplest hydrocarbon, the combustion of methane produces more heat per gram than other hydrocarbons. In addition, compared to other hydrocarbon fuels, burning methane produces less carbon dioxide for each unit of heat released.

In the form of natural gas, methane is regularly distributed via gas pipelines. In many cities, it is piped into homes for domestic heating and cooking purposes. Moreover, large quantities are burned to drive gas or steam turbines, to generate electricity.

When biogas is used as a fuel, it provides a convenient way to turn waste into electricity. The process of producing biogas decreases the amount of waste to be disposed of and destroys disease-causing microbes that are present in the waste stream.

Industrial uses

In the chemical industry, methane is the feedstock of choice for the production of hydrogen, methanol, acetic acid, and acetic anhydride. To produce any of these chemicals, methane is first made to react with steam in the presence of a nickel catalyst at high temperatures (700–1,100 °C). The chemical equation is as follows:

CH4 + H2O → CO + 3H2

The product, known as "synthesis gas," is a mixture of carbon monoxide and hydrogen. Synthesis gas is then manipulated to produce the intended products.

Moreover, acetylene is prepared by passing methane through an electric arc. When methane is made to react with chlorine gas, various chloromethanes are produced: chloromethane, dichloromethane, chloroform, and carbon tetrachloride. The use of these chemicals, however, is declining. Acetylene may be replaced by less costly substitutes, and the chloromethanes are used less often because of health and environmental concerns.

Greenhouse gas

Methane in the Earth's atmosphere is an important "greenhouse gas" that contributes to the "greenhouse effect." The Earth absorbs some of the Sun's energy and then emits energy at longer wavelengths. Greenhouse gases (including water vapor, carbon dioxide, and methane) absorb the heat being emitted and prevent it from escaping into space. In this manner, greenhouse gases play a vital role in keeping the planet warm enough for human habitation.

The current concern about global warming is based on reports that the concentrations of greenhouse gases have risen in recent years, mainly as a result of human activities, leading to an upward trend in the Earth's temperature [7]. Some have contended that if this warming trend is not reversed, it could soon lead to dire consequences. This subject, however, is the focus of intense study and debate.

In the case of methane, its concentration has reportedly increased by about 150 percent since 1750. In addition, its "global warming potential" is estimated to be 23 over a 100-year period. In other words, when averaged over one hundred years, each kilogram of methane warms the Earth 23 times as much as the same mass of carbon dioxide. Nonetheless, the rates of emission of methane by different sources in the biosphere are highly variable and difficult to assess. Consequently, it is difficult to predict future concentrations of methane in the atmosphere [8].

Extraterrestrial methane

Methane has been detected or is believed to exist in several locations of the solar system beyond our planet, as listed below.

Traces of methane gas are present in the thin atmosphere of the Earth's Moon. Methane has also been detected in interstellar clouds.

See also

References
ISBN links support NWE through referral fees

  • McMurry, John. 2004. Organic Chemistry, 6th ed. Belmont, CA: Brooks/Cole. ISBN 0534420052.
  • Morrison, Robert T., and Robert N. Boyd. 1992. Organic Chemistry, 6th ed. Englewood Cliffs, NJ: Prentice Hall. ISBN 0136436692.
  • Solomons, T.W. Graham, and Craig B. Fryhle. 2004. Organic Chemistry, 8th ed. Hoboken, NJ: John Wiley. ISBN 0471417998.


 
Alkanes

methane
CH4

|
 

ethane
C2H6

|
 

propane
C3H8

|
 

butane
C4H10

|
 

pentane
C5H12

|
 

hexane
C6H14

heptane
C7H16

|
 

octane
C8H18

|
 

nonane
C9H20

|
 

decane
C10H22

|
 

undecane
C11H24

|
 

dodecane
C12H26

 


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