Difference between revisions of "Oxygen"
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'''Oxygen''' (''[[Elements on Mars|periodic table]] symbol:'' O<sup>8</sup>) is a chemical element that can be found in the [[atmosphere]] and in most [[minerals]] on [[Mars]]. Almost half of the mass of the Martian crust is Oxygen, bound up in various minerals. Oxygen is created in stars from the fusion of [[Carbon]] and [[Helium]]. Oxygen has 8 protons and the most common isotope is oxygen 16. O<sub>17</sub> and O<sub>18</sub> exist and are stable. Oxygen needs two electrons to fill its outer electron shell, which makes it a powerful oxidizer. (Only [[Fluorine]] is a more powerful oxidizer, but Fluorine is a fairly rare element.) | '''Oxygen''' (''[[Elements on Mars|periodic table]] symbol:'' O<sup>8</sup>) is a chemical element that can be found in the [[atmosphere]] and in most [[minerals]] on [[Mars]]. Almost half of the mass of the Martian crust is Oxygen, bound up in various minerals. Oxygen is created in stars from the fusion of [[Carbon]] and [[Helium]]. Oxygen has 8 protons and the most common isotope is oxygen 16. O<sub>17</sub> and O<sub>18</sub> exist and are stable. Oxygen needs two electrons to fill its outer electron shell, which makes it a powerful oxidizer. (Only [[Fluorine]] is a more powerful oxidizer, but Fluorine is a fairly rare element.) | ||
+ | |||
+ | Oxygen is found in the Martian [[Atmosphere]] in small quantities, produced by [[Photochemistry]]. | ||
[[Image:alga_and_bubbles.jpg|thumb|right|200px|Alga producing oxygen]] | [[Image:alga_and_bubbles.jpg|thumb|right|200px|Alga producing oxygen]] | ||
=Relevance for life= | =Relevance for life= | ||
− | The metabolism of [[human|human beings]], [[ | + | The metabolism of [[human|human beings]], [[animals|animals]] and aerobic [[microbes]] depends on oxygen. The atmosphere of Mars contains only 0,15 % oxygen, which is not enough to support animal or human life. The minimum concentration required is about 15% oxygen, or 100 times more (depending on the atmospheric pressure)(reference needed). |
− | *Oxygen is used by life within the Carbon cycle, where CO2 is consumed by plants through photosynthesis, liberating oxygen than can then be used by plants for other processes | + | *Oxygen is used by life within the Carbon cycle, where CO2 is consumed by plants through photosynthesis, liberating oxygen than can then be used by plants for other processes or by animals to support the combustion of carbohydrates, that liberates CO2, completing the cycle. |
*Biological combustion also produces water, and therefore consumes oxygen that is removed from the biological cycle. But in tiny amounts compared to the other requirements that life has for water as a solvent and media for chemical reactions. However, Oxygen is eventually returned to the atmosphere through photodissociation of water with UV light in the upper atmosphere. | *Biological combustion also produces water, and therefore consumes oxygen that is removed from the biological cycle. But in tiny amounts compared to the other requirements that life has for water as a solvent and media for chemical reactions. However, Oxygen is eventually returned to the atmosphere through photodissociation of water with UV light in the upper atmosphere. | ||
*If Oxygen becomes common in a future Mars' terraformed atmosphere, an [[Ozone]] layer will also build up 'naturally' which will protect the surface from [[Ultraviolet]] light. | *If Oxygen becomes common in a future Mars' terraformed atmosphere, an [[Ozone]] layer will also build up 'naturally' which will protect the surface from [[Ultraviolet]] light. | ||
− | = | + | =Oxygen production= |
Oxygen can be produced [[Atmospheric processing|in situ]]: | Oxygen can be produced [[Atmospheric processing|in situ]]: | ||
Line 25: | Line 27: | ||
*in [[Photobioreactor|photobioreactors]] by algae. | *in [[Photobioreactor|photobioreactors]] by algae. | ||
*by reduction of [[carbon dioxide]] from the martian atmosphere, or [[w:Carbonates_on_Mars|carbonate]] minerals via either molten salt reduction<ref>https://eprints.lib.hokudai.ac.jp/dspace/bitstream/2115/57796/1/CO2OtakeREMTRev2.pdf</ref> or via [[Carbon_Dioxide_Scrubbers|MOXIE]] style solid oxide electrolysis. | *by reduction of [[carbon dioxide]] from the martian atmosphere, or [[w:Carbonates_on_Mars|carbonate]] minerals via either molten salt reduction<ref>https://eprints.lib.hokudai.ac.jp/dspace/bitstream/2115/57796/1/CO2OtakeREMTRev2.pdf</ref> or via [[Carbon_Dioxide_Scrubbers|MOXIE]] style solid oxide electrolysis. | ||
− | *by reduction of oxide minerals, either at low temperature in aqueous solution<ref>https://link.springer.com/article/10.1007/s10800-017-1127-5</ref> or at high temperature in molten | + | *by reduction of oxide minerals, either at low temperature in aqueous solution<ref>https://link.springer.com/article/10.1007/s10800-017-1127-5</ref> or at high temperature in molten salts<ref>https://link.springer.com/article/10.1007/s10800-017-1143-5</ref>. This is required to free up metals from many ores, such as Iron ore (Fe2O3) or aluminum ore (Al2O3). |
*by [[electrolysis]] of [[water]] | *by [[electrolysis]] of [[water]] | ||
*by the decomposition of [[Perchlorate|perchlorates]] in the soil. | *by the decomposition of [[Perchlorate|perchlorates]] in the soil. | ||
Line 33: | Line 35: | ||
==Electrolysis== | ==Electrolysis== | ||
− | Submarines are a fairly good analog for a Mars habitat, a sealed system that has to manufacture oxygen and remove carbon dioxide. How Submarines produce oxygen<ref>Destin Sandlin (2021). How Do Nuclear Submarines Make Oxygen?- Smarter Every Day 251 [Video]. https://www.youtube.com/watch?v=g3Ud6mHdhlQ; SmarterEveryDay.</ref> | + | Submarines are a fairly good analog for a Mars habitat, a sealed system that has to manufacture oxygen and remove carbon dioxide. How Submarines produce oxygen<ref>Destin Sandlin (2021). How Do Nuclear Submarines Make Oxygen?- Smarter Every Day 251 [Video]. https://www.youtube.com/watch?v=g3Ud6mHdhlQ; SmarterEveryDay.</ref> using electrolysis. |
+ | |||
+ | Two electrodes, positive and negative are charged using an electric current. Pure water is required because salt water will create chlorine gas which can be deadly if not adequately separated. On a submarine, reverse osmosis is used to filter out the salt, the same might be done on Mars. The pure water has potassium hydroxide (KOH) added as a catalyst to make the electrolysis more efficient. The hydrogen created in a submarine is exhausted from the boat, but would represent a vary valuable co-product on Mars. | ||
+ | |||
+ | ==Biosynthesis== | ||
− | On a | + | Oxygen is produced by plants, algae and monocellular organisms as a byproduct of photosynthesis. Since food is required for the settlement inhabitants and oxygen is a natural by-product of food production, oxygen is inherent in the operation of a life support system that uses any form of photosynthesis in its operation, such as Melissa(reference) or greenhouses. |
+ | ==Metal production== | ||
+ | |||
+ | Most metals are present on Mars as oxides. Processes that remove the oxygen from the metal are required to create metals for industry. On Earth, the most common methods use carbon and produce a metal + CO2. On Mars, since there are no known carbon reservoirs, the required carbon would need to be produced through processing of the CO2 atmosphere, that also liberates oxygen. Alternatively, hydrogen could be used with catalysts to create a metal + water +O2, in varying quantities depending on the process. Again, producing hydrogen from water frees up oxygen. So the metal processing industry on Mars is likely to generate excess oxygen, than can be stored or liberated into the Martian atmosphere. | ||
+ | |||
+ | =Oxygen removal= | ||
+ | Excess oxygen in the atmosphere is both a health and a fire risk. Excess oxygen can cause Hyperoxia. | ||
+ | |||
+ | Oxygen can be removed from the atmosphere by refrigeration, adsorption or combustion. | ||
+ | ==Refrigeration== | ||
+ | Refrigeration is the classic way of producing oxygen on Earth, and can be used to reduce oxygen concentration in a Martian settlement. A stream of atmosphere is passed through a chiller, where is is cooled to its condensation temperature. the liquid oxygen is removed through a valve, and can be used in various processes for the settlement. | ||
+ | This process also removes water, that can easily be added back. | ||
+ | ==Adsorption== | ||
+ | Adsorption can selectively remove oxygen from the atmosphere using an appropriate media bed through which the oxygen rich atmosphere is passed. The media eventually saturates with oxygen and can be regenerated, generally using heat to free up the oxygen, and be reused indefinitely. | ||
+ | ==Combustion== | ||
+ | Combustion is used on Earth in industrial processes to produce a non corrosive atmosphere of CO2 and nitrogen. The oxygen is burned with natural gas, the water is removed by condensation and the resulting CO2+nitrogen mix is relatively inert and can be used, for example, as an atmosphere for processes that involve explosive iron dust. | ||
+ | CO2 can be removed by biological processes or by cooling and adsorption, as for oxygen itself. | ||
=Gas monitoring= | =Gas monitoring= | ||
− | Monitoring the atmosphere in every compartment | + | Monitoring the atmosphere in every compartment of a Martian habitat is required in order to ensure the proper distribution of oxygen and to measure the concentration of contaminants, as these can cause health or fire risks. CO2 is usually monitored as a proxy for oxygen, as the toxic concentration of CO2 is reached much faster than the lowest threshold for respiration. |
+ | The main gasses that should be monitored are: O<sub>2</sub>, CO<sub>2</sub>, H<sub>2</sub>, N<sub>2</sub> and H<sub>2</sub>O. Other gasses monitored should be: CO, refrigerants, if present and Volatile Organic carbons (VOCs). Regular calibration of gas monitoring systems need to be carried regularly, as all these sensors are susceptible to signal drift and contamination of the sensor elements. Redundancy of the sensors should be implemented when possible. | ||
− | + | Handheld gas probes are often used in an industrial context on Earth, or in submarines. These need to be calibrated, and can be used in situations where permanent sensors are not available. | |
− | + | Gas concentrations in areas where there are plants and greenhouses are very dynamic. CO<sub>2</sub> concentrations can vary dramatically, especially in small habitats. Plants tend to overproduce oxygen over time, and therefore a method for removing excess oxygen from the atmosphere of a Martian settlement is required. | |
=Emergency supplies= | =Emergency supplies= | ||
− | + | Emergency supplies or backup supplies in small vehicles is provided by burning a Chlorate candle (aka an Oxygen candle). Iron (Fe) and Sodium Chlorate (NaClO<sub>3</sub>). <br> | |
Fe + O<sub>2</sub> -> Fe<sub>2</sub>O<sub>2</sub> + heat<br> | Fe + O<sub>2</sub> -> Fe<sub>2</sub>O<sub>2</sub> + heat<br> | ||
heat + NaClO<sub>3</sub> -> NaCl + O<sub>2</sub><br> | heat + NaClO<sub>3</sub> -> NaCl + O<sub>2</sub><br> | ||
− | *Oxygen candles are used on the space station. | + | *Oxygen candles are used on the space station. The self oxidizing reaction of the oxygen candle cannot be extinguished, it has to burn out. |
− | + | ||
+ | =Oxygen and fires= | ||
+ | *Fires are classified in various ways. | ||
=Uses for oxygen= | =Uses for oxygen= | ||
*[[Propellant]]. Oxygen is often chosen as an oxidizer for chemical propulsion. | *[[Propellant]]. Oxygen is often chosen as an oxidizer for chemical propulsion. | ||
− | *[[Air|Atmospheric component]]. The standard Earth atmosphere contains 21% Oxygen. | + | *[[Air|Atmospheric component]]. The standard Earth atmosphere contains 21% Oxygen. Oxygen regulation is an essential component of life support. |
− | *Chemical reagent as an oxidizer. | + | *Chemical reagent as an oxidizer. Often used in water treatment in the form of Ozone (O3). |
+ | *Used in welding, cutting and fabrication processes. | ||
− | = | + | =References= |
[[lunarp:Oxygen|Oxygen<sup><b>lunarp</b></sup>]] on Lunarpedia. | [[lunarp:Oxygen|Oxygen<sup><b>lunarp</b></sup>]] on Lunarpedia. |
Latest revision as of 06:44, 29 November 2024
O | 8 |
Oxygen |
Abundance: 0.15% atmosphere 46,6% crust
Oxygen (periodic table symbol: O8) is a chemical element that can be found in the atmosphere and in most minerals on Mars. Almost half of the mass of the Martian crust is Oxygen, bound up in various minerals. Oxygen is created in stars from the fusion of Carbon and Helium. Oxygen has 8 protons and the most common isotope is oxygen 16. O17 and O18 exist and are stable. Oxygen needs two electrons to fill its outer electron shell, which makes it a powerful oxidizer. (Only Fluorine is a more powerful oxidizer, but Fluorine is a fairly rare element.)
Oxygen is found in the Martian Atmosphere in small quantities, produced by Photochemistry.
Contents
Relevance for life
The metabolism of human beings, animals and aerobic microbes depends on oxygen. The atmosphere of Mars contains only 0,15 % oxygen, which is not enough to support animal or human life. The minimum concentration required is about 15% oxygen, or 100 times more (depending on the atmospheric pressure)(reference needed).
- Oxygen is used by life within the Carbon cycle, where CO2 is consumed by plants through photosynthesis, liberating oxygen than can then be used by plants for other processes or by animals to support the combustion of carbohydrates, that liberates CO2, completing the cycle.
- Biological combustion also produces water, and therefore consumes oxygen that is removed from the biological cycle. But in tiny amounts compared to the other requirements that life has for water as a solvent and media for chemical reactions. However, Oxygen is eventually returned to the atmosphere through photodissociation of water with UV light in the upper atmosphere.
- If Oxygen becomes common in a future Mars' terraformed atmosphere, an Ozone layer will also build up 'naturally' which will protect the surface from Ultraviolet light.
Oxygen production
Oxygen can be produced in situ:
- in greenhouses by plants.
- in photobioreactors by algae.
- by reduction of carbon dioxide from the martian atmosphere, or carbonate minerals via either molten salt reduction[1] or via MOXIE style solid oxide electrolysis.
- by reduction of oxide minerals, either at low temperature in aqueous solution[2] or at high temperature in molten salts[3]. This is required to free up metals from many ores, such as Iron ore (Fe2O3) or aluminum ore (Al2O3).
- by electrolysis of water
- by the decomposition of perchlorates in the soil.
- by thermal decomposition of water through the Sulfur/Iodine[4] or Zinc/Sulfur/Iodine[5] cycles.
Electrolysis
Submarines are a fairly good analog for a Mars habitat, a sealed system that has to manufacture oxygen and remove carbon dioxide. How Submarines produce oxygen[6] using electrolysis.
Two electrodes, positive and negative are charged using an electric current. Pure water is required because salt water will create chlorine gas which can be deadly if not adequately separated. On a submarine, reverse osmosis is used to filter out the salt, the same might be done on Mars. The pure water has potassium hydroxide (KOH) added as a catalyst to make the electrolysis more efficient. The hydrogen created in a submarine is exhausted from the boat, but would represent a vary valuable co-product on Mars.
Biosynthesis
Oxygen is produced by plants, algae and monocellular organisms as a byproduct of photosynthesis. Since food is required for the settlement inhabitants and oxygen is a natural by-product of food production, oxygen is inherent in the operation of a life support system that uses any form of photosynthesis in its operation, such as Melissa(reference) or greenhouses.
Metal production
Most metals are present on Mars as oxides. Processes that remove the oxygen from the metal are required to create metals for industry. On Earth, the most common methods use carbon and produce a metal + CO2. On Mars, since there are no known carbon reservoirs, the required carbon would need to be produced through processing of the CO2 atmosphere, that also liberates oxygen. Alternatively, hydrogen could be used with catalysts to create a metal + water +O2, in varying quantities depending on the process. Again, producing hydrogen from water frees up oxygen. So the metal processing industry on Mars is likely to generate excess oxygen, than can be stored or liberated into the Martian atmosphere.
Oxygen removal
Excess oxygen in the atmosphere is both a health and a fire risk. Excess oxygen can cause Hyperoxia.
Oxygen can be removed from the atmosphere by refrigeration, adsorption or combustion.
Refrigeration
Refrigeration is the classic way of producing oxygen on Earth, and can be used to reduce oxygen concentration in a Martian settlement. A stream of atmosphere is passed through a chiller, where is is cooled to its condensation temperature. the liquid oxygen is removed through a valve, and can be used in various processes for the settlement. This process also removes water, that can easily be added back.
Adsorption
Adsorption can selectively remove oxygen from the atmosphere using an appropriate media bed through which the oxygen rich atmosphere is passed. The media eventually saturates with oxygen and can be regenerated, generally using heat to free up the oxygen, and be reused indefinitely.
Combustion
Combustion is used on Earth in industrial processes to produce a non corrosive atmosphere of CO2 and nitrogen. The oxygen is burned with natural gas, the water is removed by condensation and the resulting CO2+nitrogen mix is relatively inert and can be used, for example, as an atmosphere for processes that involve explosive iron dust. CO2 can be removed by biological processes or by cooling and adsorption, as for oxygen itself.
Gas monitoring
Monitoring the atmosphere in every compartment of a Martian habitat is required in order to ensure the proper distribution of oxygen and to measure the concentration of contaminants, as these can cause health or fire risks. CO2 is usually monitored as a proxy for oxygen, as the toxic concentration of CO2 is reached much faster than the lowest threshold for respiration.
The main gasses that should be monitored are: O2, CO2, H2, N2 and H2O. Other gasses monitored should be: CO, refrigerants, if present and Volatile Organic carbons (VOCs). Regular calibration of gas monitoring systems need to be carried regularly, as all these sensors are susceptible to signal drift and contamination of the sensor elements. Redundancy of the sensors should be implemented when possible.
Handheld gas probes are often used in an industrial context on Earth, or in submarines. These need to be calibrated, and can be used in situations where permanent sensors are not available.
Gas concentrations in areas where there are plants and greenhouses are very dynamic. CO2 concentrations can vary dramatically, especially in small habitats. Plants tend to overproduce oxygen over time, and therefore a method for removing excess oxygen from the atmosphere of a Martian settlement is required.
Emergency supplies
Emergency supplies or backup supplies in small vehicles is provided by burning a Chlorate candle (aka an Oxygen candle). Iron (Fe) and Sodium Chlorate (NaClO3).
Fe + O2 -> Fe2O2 + heat
heat + NaClO3 -> NaCl + O2
- Oxygen candles are used on the space station. The self oxidizing reaction of the oxygen candle cannot be extinguished, it has to burn out.
Oxygen and fires
- Fires are classified in various ways.
Uses for oxygen
- Propellant. Oxygen is often chosen as an oxidizer for chemical propulsion.
- Atmospheric component. The standard Earth atmosphere contains 21% Oxygen. Oxygen regulation is an essential component of life support.
- Chemical reagent as an oxidizer. Often used in water treatment in the form of Ozone (O3).
- Used in welding, cutting and fabrication processes.
References
Oxygenlunarp on Lunarpedia.
- ↑ https://eprints.lib.hokudai.ac.jp/dspace/bitstream/2115/57796/1/CO2OtakeREMTRev2.pdf
- ↑ https://link.springer.com/article/10.1007/s10800-017-1127-5
- ↑ https://link.springer.com/article/10.1007/s10800-017-1143-5
- ↑ https://doi.org/10.1016/j.ijhydene.2006.05.013
- ↑ https://doi.org/10.1016/j.ijhydene.2015.11.049
- ↑ Destin Sandlin (2021). How Do Nuclear Submarines Make Oxygen?- Smarter Every Day 251 [Video]. https://www.youtube.com/watch?v=g3Ud6mHdhlQ; SmarterEveryDay.