Difference between revisions of "Carbon"
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− | + | {{element | |
+ | |float=right | ||
+ | |elementName=Carbon | ||
+ | |elementSymbol=C | ||
+ | |protons=6 | ||
+ | |abundance=32% ([[atmosphere]] <br> as [[Carbon dioxide|CO<sub>2</sub>]] and [[Carbon monoxide|CO]]) | ||
+ | }} | ||
− | + | '''Carbon,''' ''[[Elements on Mars|periodic table]] C,'' is a nonmetallic [[Elements on Mars|element]]. carbon on Mars is abundant in the the form of [[carbon dioxide]]. Elemental carbon can be produced via the [[bosch reaction]]. One of the important uses of carbon in a colony would be in the production of [[plastics]] and [[hydrocarbons]].<br /> | |
− | Carbon is | + | Carbon makes up about 0.39%<ref name="Phillips" /> of the matter in the solar system. |
− | {{ | + | The most common isotope is carbon 12, carbon 14 is used for radiocarbon dating. |
+ | |||
+ | See [[Carbon cycle]] for the carbon cycles on Earth. | ||
+ | |||
+ | ==Origin== | ||
+ | Massive stars (more than about half a solar mass) are capable of burning helium in the so-called triple-alpha process:<br /> | ||
+ | <math>{}^4 He + {}^4 He \rightleftharpoons {}^8 Be </math><br /> | ||
+ | <math>{}^4 He + {}^8 Be \rightleftharpoons {}^{12} C^\star</math><br /> | ||
+ | <math>{}^{12} C^\star \rightarrow {}^{12} C + 2\gamma</math> or <math>{}^{12} C^\star \rightarrow {}^{12} C + e^{+} + e^{-}</math><br />In brief, two helium-4 nuclei are fused to create highly unstable beryllium-8 nuclei. While most of these nuclei simply decay back to helium, a small fraction will fuse with another helium-4 nucleus to form yet another unstable nucleus, an excited state of carbon-12 (here denoted <math>{}^{12}C^\star</math>). While once again most of these nuclei will simply decay back to helium-4 and beryllium-8, a tiny fraction will instead randomly decay to the ground state of carbon-12, where they will remain. Over time, this process produces a lot of energy and carbon.<ref name="Phillips">A.C. Phillips - ''The physics of stars'' 2nd ed. 1999. Wiley. ISBN 0-471-98798-0. pp. 127-135.</ref><br />Once C12 has been created in a star, it can speed the fusion process using the CNO cycle (where C12 absorbs successive protons, becoming first Nitrogen then Oxygen, which then absorbs another proton and splits off a Helium nuclei and returns to C12). The CNO cycle acts as a catalyst, allowing stars to burn Hydrogen into Helium faster, increasing their temperature. | ||
+ | |||
+ | ==Role of carbon-formation in the future of Mars== | ||
+ | Our sun, while massive enough to fuse helium, has not yet begun this process. When the helium core ignites in the distant future, the core will become very hot and dense, causing the outer layers of the sun to expand and cool<ref name="Phillips" />. This "red giant" phase of the sun's life will almost certainly destroy all life on Earth<ref name="RybickiDenis">K.R. Rybicki & C. Denis - ''On the Final Destiny of the Earth and the Solar System'' 2001. Icarus, Vol. 151(1) pp. 130–137. Abstract available [http://www.sciencedirect.com/science/article/pii/S0019103501965911 here].</ref><ref name="SchröderSmith">K.-P. Schröder & R.C. Smith - ''Distant future of the Sun and Earth revisited'' 2008. Monthly Notices of the Royal Astronomical Society, Vol. 386(1) pp. 155–163. Abstract available [http://onlinelibrary.wiley.com/doi/10.1111/j.1365-2966.2008.13022.x/abstract;jsessionid=4AB9DD7C567EA056FE9B3BE775B7E346.d01t03?deniedAccessCustomisedMessage=&userIsAuthenticated=false here].</ref>, quite possibly evaporating the planet, but Mars is likely to survive<ref name="RybickiDenis" />. Whether conditions on Mars would be tolerable for any Earth-origin lifeforms at that time depends on less accurately known aspects of the process, mainly how much mass the sun loses and how much drag the planet experiences, but it seems likely<ref name="LopezSchneiderDanchi">B. Lopez, J. Schneider & W.C. Danchi - '' Can Life Develop in the Expanded Habitable Zones around Red Giant Stars? '' 2005. The Astrophysical Journal, Vol. 627(2). Full text [http://iopscience.iop.org/0004-637X/627/2/974 here].</ref> that the planet will be reasonably tolerable for hundreds of millions, if not billions of years. | ||
+ | |||
+ | ==Abundance== | ||
+ | Because there are no stable atomic nuclei of mass numbers 5 and 8, the triple-alpha process is the only way in which stars can create elements beyond helium on a large scale<ref name="Phillips" />. As a result, carbon is the fourth most common element in the universe. (It lies after oxygen because the same stars that create carbon-12 mostly convert it into oxygen-16 by the addition of another helium-4 nucleus<ref name="Phillips" />.) | ||
+ | |||
+ | ==[[In-situ resource utilization|In situ production]]== | ||
+ | Carbon is readily available on Mars in the form of CO<sub>2</sub> from the atmosphere, and from [[w:Carbonates_on_Mars|carbonate]] deposits in the Martian regolith. Elemental Carbon may be produced via the [[bosch reaction]]. The availability of Elemental Carbon as diamonds or graphite will need to be evaluated by exploration. Elemental carbon as graphene, carbon nanotubes or Buckyballs may be useful for certain applications. | ||
+ | |||
+ | ==Organic Chemistry== | ||
+ | Carbon is an essential element in [[organic chemistry|organic molecules]]. Atmospheric CO<sub>2</sub> and CO should be adequate as sources for all hydrocarbons and organic chemistry requirements for a settlement. | ||
+ | |||
+ | ==Carbon in terraforming== | ||
+ | If more buried / frozen carbon dioxide (CO<sub>2</sub>) were to be released to the Martian atmosphere, the planet would warm since CO<sub>2</sub> is a [[Greenhouse gas]]. This would help [[Terraforming]] the planet. However, to completely terraform Mars (to give it a breathable atmosphere), the CO<sub>2</sub> would have to be drawn down to low levels which would ''cool'' the planet. See [[Carbon cycle]] for more information. | ||
+ | |||
+ | ==See Also== | ||
+ | |||
+ | *[[Hydrocarbon synthesis]] | ||
+ | |||
+ | *[[In-situ resource utilization]] | ||
+ | |||
+ | ==References== | ||
+ | <references /> | ||
+ | |||
+ | [[Category:Materials]] |
Latest revision as of 08:11, 25 October 2024
C | 6 |
Carbon |
Abundance: 32% (atmosphere
as CO2 and CO)
Carbon, periodic table C, is a nonmetallic element. carbon on Mars is abundant in the the form of carbon dioxide. Elemental carbon can be produced via the bosch reaction. One of the important uses of carbon in a colony would be in the production of plastics and hydrocarbons.
Carbon makes up about 0.39%[1] of the matter in the solar system.
The most common isotope is carbon 12, carbon 14 is used for radiocarbon dating.
See Carbon cycle for the carbon cycles on Earth.
Contents
Origin
Massive stars (more than about half a solar mass) are capable of burning helium in the so-called triple-alpha process:
or
In brief, two helium-4 nuclei are fused to create highly unstable beryllium-8 nuclei. While most of these nuclei simply decay back to helium, a small fraction will fuse with another helium-4 nucleus to form yet another unstable nucleus, an excited state of carbon-12 (here denoted ). While once again most of these nuclei will simply decay back to helium-4 and beryllium-8, a tiny fraction will instead randomly decay to the ground state of carbon-12, where they will remain. Over time, this process produces a lot of energy and carbon.[1]
Once C12 has been created in a star, it can speed the fusion process using the CNO cycle (where C12 absorbs successive protons, becoming first Nitrogen then Oxygen, which then absorbs another proton and splits off a Helium nuclei and returns to C12). The CNO cycle acts as a catalyst, allowing stars to burn Hydrogen into Helium faster, increasing their temperature.
Role of carbon-formation in the future of Mars
Our sun, while massive enough to fuse helium, has not yet begun this process. When the helium core ignites in the distant future, the core will become very hot and dense, causing the outer layers of the sun to expand and cool[1]. This "red giant" phase of the sun's life will almost certainly destroy all life on Earth[2][3], quite possibly evaporating the planet, but Mars is likely to survive[2]. Whether conditions on Mars would be tolerable for any Earth-origin lifeforms at that time depends on less accurately known aspects of the process, mainly how much mass the sun loses and how much drag the planet experiences, but it seems likely[4] that the planet will be reasonably tolerable for hundreds of millions, if not billions of years.
Abundance
Because there are no stable atomic nuclei of mass numbers 5 and 8, the triple-alpha process is the only way in which stars can create elements beyond helium on a large scale[1]. As a result, carbon is the fourth most common element in the universe. (It lies after oxygen because the same stars that create carbon-12 mostly convert it into oxygen-16 by the addition of another helium-4 nucleus[1].)
In situ production
Carbon is readily available on Mars in the form of CO2 from the atmosphere, and from carbonate deposits in the Martian regolith. Elemental Carbon may be produced via the bosch reaction. The availability of Elemental Carbon as diamonds or graphite will need to be evaluated by exploration. Elemental carbon as graphene, carbon nanotubes or Buckyballs may be useful for certain applications.
Organic Chemistry
Carbon is an essential element in organic molecules. Atmospheric CO2 and CO should be adequate as sources for all hydrocarbons and organic chemistry requirements for a settlement.
Carbon in terraforming
If more buried / frozen carbon dioxide (CO2) were to be released to the Martian atmosphere, the planet would warm since CO2 is a Greenhouse gas. This would help Terraforming the planet. However, to completely terraform Mars (to give it a breathable atmosphere), the CO2 would have to be drawn down to low levels which would cool the planet. See Carbon cycle for more information.
See Also
References
- ↑ 1.0 1.1 1.2 1.3 1.4 A.C. Phillips - The physics of stars 2nd ed. 1999. Wiley. ISBN 0-471-98798-0. pp. 127-135.
- ↑ 2.0 2.1 K.R. Rybicki & C. Denis - On the Final Destiny of the Earth and the Solar System 2001. Icarus, Vol. 151(1) pp. 130–137. Abstract available here.
- ↑ K.-P. Schröder & R.C. Smith - Distant future of the Sun and Earth revisited 2008. Monthly Notices of the Royal Astronomical Society, Vol. 386(1) pp. 155–163. Abstract available here.
- ↑ B. Lopez, J. Schneider & W.C. Danchi - Can Life Develop in the Expanded Habitable Zones around Red Giant Stars? 2005. The Astrophysical Journal, Vol. 627(2). Full text here.